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 Iversity of California. 
 
 FROM TIIF. 1 IKRARY < >F 
 
 FRANCIS LIEBER, 
 
 Professor of History jiml Law- in Columbia Colk'jro, Now York. 
 TJU: GUT of 
 
 MICHAEL REESE, 
 
CAPTAIN HENRY KATER, V. PRES : R. S . 
 
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 KEVs DIONYSIITS LARDNER,L,.IuD. F.R.S. 1L fcE . 
 
 n B\' CLMVEY 6c I^EA 
 
 Hales Steam. Pr res. 
 
THE 
 
 CABINET 
 
 OF 
 
 NATURAL PHILOSOPHY. 
 
 CONDUCTED BY THE 
 
 REV. D10NYSIUS LARDNER, LL. D, F. R. S. L. & E. 
 M.R.I.A. F.L.S. F.Z.S. Hon. F.C.P.S. M. Ast. S. &c. &c. 
 
 ASSISTED BY 
 
 EMINENT LITERARY MEN. 
 
 TREATISE ON MECHANICS, 
 
 BY 
 
 CAPT. HENRY KATER, V. PRES. R. S. &c. 
 
 AND THE 
 
 REV. DIONYSIUS LARDNER, LL. D. F.R.S. L. & E. &c. 
 
 PHILADELPHIA : 
 CAREY AND LEA CHESTNUT STREET. 
 
 1832. 
 

 llf'J J/.-H 
 
TREATISE 
 
 MECHANICS 
 
 BY 
 
 CAPTAIN HENRY KATER, V. PRES. R. S. 
 
 M 
 
 REV. DIONYSIUS LARDNER, LL. D. F. R. S. L. & E. 
 
 
 PHILADELPHIA : 
 CAREY & LEA CHESTNUT-STREET. 
 
 1832. 
 
ADVERTISEMENT. 
 
 THIS Treatise being the joint production of two persons, 
 it is right to state the portions of it which are the exclusive 
 work of each. The chapter on Balances and Pendulums, 
 the instruments on which the measurement of weight and 
 time depends, has been written by Captain Kater. For the 
 remainder of the volume. Dr. Lardner is responsible. 
 
CONTENTS. 
 
 CHAPTER I. 
 
 PROPERTIES OF MATTER. 
 
 Organs of Sense. Sensations. Properties or Qualities. Observation. 
 Comparison and Generalization. Particular and general Qualities. Mag- 
 nitude. Size. Volume. Lines. Surfaces. Edges. Area. 
 Length. Impenetrability. Apparent Penetration. Figure. Different 
 from Volume. Atoms. Molecules. Matter separable. Particles. 
 Force. Cohesion of Atoms. Hypothetical Phrases unnecessary. 
 Attraction Page 1 
 
 CHAPTER II. 
 
 PROPERTIES OF MATTER, CONTINUED. 
 
 Divisibility. Unlimited Divisibility. Wollaston's micrometric Wire. 
 Method of making it. Thickness of a Soap Bubble. Wings of Insects. 
 Gilding of Embroidery. Globules of the Blood. Animalcules. Their 
 minute Organization. Ultimate Atoms. Crystals. Porosity. Volume. 
 Density. Quicksilver passing through Pores of Wood. Filtration. 
 Porosity of Hydrophane. Compressibility. Elasticity. Dilatability. 
 Heat. Contraction of Metal used to restore the Perpendicular to Walls of 
 a Building. Impenetrability of Air. Compressibility of it. Elasticity of 
 it. Liquids not absolutely incompressible, Experiments. Elasticity 
 of Fluids. Aeriform Fluids. Domestic Fire-Box. Evolution of Heat 
 by compressed Air 7 
 
 CHAPTER III. 
 
 INERTIA. 
 
 Inertia. Matter incapable of spontaneous Change. Impediments to Motion. 
 Motion of the Solar System. Law of Nature. Spontaneous Motion. 
 Immateriality of the thinking and willing Principles. Language used to 
 express Inertia sometimes faulty. Familiar Examples of Inertia 23 
 
v CONTENTS. 
 
 * 
 
 CHAPTER IV. 
 
 ACTION AND REACTION. 
 
 Inertia in a single Body. Consequences of Inertia in two or more Bodies. 
 Examples. Effects of Impact. Motion not estimated by Speed or Veloci- 
 ty alone. Examples. Rule for estimating the Quantity of Motion. Ac- 
 tion and Reaction. Examples of. Velocity of two Bodies after Impact. 
 Magnet and Iron. Feather and Cannon Ball impinging. Newton's 
 Laws of Motion. Inutility of. 29 
 
 CHAPTERS. 
 
 COMPOSITION AND RESOLUTION OF FORCE. 
 
 Motion and Pressure. Force. Attraction. Parallelogram of Forces. 
 Resultant. Components. Composition of Force. Resolution of Force. 
 
 Illustrative Experiments. Composition of Pressures. Theorems regu- 
 lating Pressures also regulate Motion. Examples. Resolution of Motion. 
 
 Forces in Equilibrium. Composition of Motion and Pressure. Illustra- 
 tions. Boat in a Current. Motions of Fishes. Flight of Birds. Sails 
 of a Vessel. Tacking. Equestrian Feats. Absolute and relative 
 Motion 41 
 
 CHAPTER VI. 
 
 ATTRACTION. 
 
 Impulse. Mechanical State of Bodies. Absolute Rest. Uniform and rec- 
 tilinear Motion. Attractions. Molecular or atomic. Interstitial Spaces 
 in Bodies. Repulsion and Attraction. Cohesion. In Solids and Fluids. 
 Manufacture of Shot. Capillary Attractions. Shortening of Rope by 
 Moisture. Suspension of Liquids in capillary Tubes. Capillary Siphon. 
 
 Affinity between Quicksilver and Gold. Examples of Affinity. Sul- 
 phuric Acid and Water. Oxygen and Hydrogen. Oxygen and Quick- 
 silver. Magnetism. Electricity and Electro-Magnetism. Gravitation. 
 
 Its Law. Examples of. Depends on the Mass. Attraction between 
 the Earth and detached Bodies on its Surface. Weight. Gravitation of 
 the Earth. Illustrated by Projectiles. Plumb-Line. Cavendish's Ex- 
 periments. 53 
 
 v 
 
 CHAPTER VII. 
 
 TERRESTRIAL GRAVITY. 
 
 Phenomena of falling Bodies. Gravity greater at the Poles than Equator. 
 Heavy and light Bodies fall with equal Speed to the Earth. Experiment. 
 , Increased Velocity of falling Bodies, Principles of uniformly accelerat- 
 ed Motion. Relations between the Height? Time, and Velocity. Att- 
 wood's Machine. Retarded Motion , . . 70 
 
CONTENTS. V 
 
 CHAPTER VI11. 
 
 ON THE MOTION OF BODIES ON INCLINED PLANES AND CURVES. 
 
 Force perpendicular to a Plane. Oblique Force. Inclined Plane. Weight 
 produces Pressure and Motion. Motion uniformly accelerated. Space 
 moved through in a given Time. Increased Elevation produces increased 
 Force. Perpendicular and horizontal Plane. Final Velocity. Motion 
 down a Curve. Depends upon Velocity and Curvature. Centrifugal 
 Force Circle of Curvature. Radius of Curvature. Whirling Table. 
 Experiments. Solar System. Examples of centrifugal Force 79 
 
 CHAPTER IX. 
 
 THE CENTRE OP GRAVITY. 
 
 Terrestrial Attraction the combined Action of parallel Forces. Single 
 equivalent Force. Examples. Method of finding the Centre of Gravity. 
 
 Line of Direction. Globe. Oblate Spheroid. Prolate Spheroid. 
 Cube. Straight Wand. Flat Plate. Triangular Plate. Centre of 
 Gravity not always within the Body. A Ring. Experiments. Stable, in- 
 stable, and neutral Equilibrium. Motion and Position of the Arms and Feet. 
 
 Effect of the Knee-joint. Positions of a Dancer. Porter under a 
 Load. Motion of a Quadruped. Rope Dancing. Centre of Gravity of 
 two Bodies separated from each other. Mathematical and experimental 
 Examples. The Conservation of the Motion of the Centre of Gravity. 
 Solar System. Centre of Gravity sometimes called Centre of Inertia. . 90 
 
 CHAPTER X. 
 
 THE MECHANICAL PROPERTIES OF AN AXIS. 
 
 An Axis. Planets and common spinning Top. Oscillation or Vibration. 
 Instantaneous and continued Forces. Percussion. Continued Force. 
 Rotation. Impressed Forces. Properties of a fixed Axis difficult. 
 Movement of the Force round the Axis. Leverage of the Force. Impulse 
 perpendicular to, but not crossing, the Axis. Radius of Gyration. Cen- 
 tre of Gyration. Moment of Inertia. Principal Axes. Centre of Per- 
 cussion 108 
 
 CHAPTER XI. 
 
 OF THE PENDULUM. 
 
 Isochronism. Experiments. Simple Pendulum. Examples illustrative of 
 Length of. Experiments of Kater, Biot, Sabine, and others. Huy- 
 
 gens's C vcloidal Pendulum 123 
 
 1* 
 
*1 CONTENTS. 
 
 CHAPTER XII. 
 
 OF SIMPLE MACHINES. 
 
 Statics. Dynamics. Force. Power. Weight. Lever. Cord. In- 
 clined Plane .................................................... 135 
 
 CHAPTER XIII. 
 
 OF THE LEVER. 
 
 Arms. Fulcrum. Three Kinds of Levers. Crow-Bar. Handspike. 
 Oar. Nutcrackers. Turning Lathe. Steelyard Rectangular Lever. 
 Hammer. Load between two Bearers. Combination of Levers. 
 Equivalent Lever .................................. .... ......... 141 
 
 CHAPTER XIV. 
 
 OF WHEEL-WORK. 
 
 Wheel and Axle. Thickness of the Rope. Ways of applying the Power. 
 
 Projecting Pins. Windlass. Winch. Axle. Horizontal Wheel. 
 Tread-Mill. Cranes. Water- Wheels. Paddle- Wheel. Ratchet- 
 Wheel. Rack. Spring of a Watch. Fusee. Straps or Cords. 
 Examples of. Turning Lathe. Revolving Shafts. Spinning Machinery. 
 
 Saw-Mill. Pinion. Leaves. Crane. Spur- Wheels. Crown- 
 Wheels. Bevelled Wheels. Hunting-Cog. Chronometers. Hair- 
 Spring. Balance- Wheel ....................................... 149 
 
 CHAPTER XV. 
 
 OF THE PULLEY. 
 
 Cord: Sheave. Fixed Pulley. Fire Escapes. Single movable Pul- 
 ley. Systems of Pulleys. Smeaton's Tackle. White's Pulley. Ad- 
 vantage of. Runner. Spanish Bartons ........................ 166 
 
 CHAPTER XVI. 
 
 ON THE INCLINED PLANE, WEDGE, AND SCREW. 
 
 Inclined Plane. Effect of a Weight on. Power of. Roads. Power 
 oblique to the Plane. Plane sometimes moves under the Weight. 
 Wedge. Sometimes formed of two inclined Planes. More powerful as 
 its Angle is acute. Where used. Limits to the Angle. Screw. 
 Hunter's Screw. Examples. Micrometer Screw ................ 176 
 
CONTENTS. Yll 
 
 CHAPTER XVII. 
 
 ON THE REGULATION AND ACCUMULATION OF FORCE. 
 
 Uniformity of Operation. Irregularity of prime Mover. Water-Mill. 
 Wind-Mill. Steam Pressure. Animal Power. Spring. Regulators. 
 
 Steam-Engine. Governor. Self-acting Damper. Tachometer. 
 Accumulation of Power. Examples. Hammer. Flail. Bow-String. 
 
 Fire- Arms. Air-Gun. Steam-Gun. Inert Matter a Magazine for 
 Force. Fly- Wheel. Condensed Air. Rolling Metal. Coining- 
 Press 189 
 
 CHAPTER XVIII. 
 
 MECHANICAL CONTRIVANCES FOR MODIFYING MOTION. 
 
 Division of Motion into rectilinear and rotatory. Continued and reciprocat- 
 ing. Examples. Flowing Water. Wind. Animal Motion. Fall- 
 ing of a Body. Syringe-Pump. Hammer. Steam-Engine. Fulling- 
 Mill. Rose-Engine. Apparatus of Zureda. Leupold's Application 
 of it. Hooke's universal Joint. Circular and alternate Motion. Ex- 
 amples. Watt's Methods of connecting the Motion of the Piston with that 
 of the Beam. Parallel Motion 20t, 
 
 CHAPTER XIX. 
 
 OF FRICTION AND THE RIGIDITY OF CORDAGE. 
 
 Friction and Rigidity. Laws of Friction. Rigidity of Cordage. Strength 
 of Materials. Resistance from Friction. Independent of the Magnitude 
 of Surfaces. Examples. Vince's Experiments. Effect of Velocity. 
 Means for diminishing Friction. Friction-Wheels. Angle of Repose. 
 Best Angle of Draught. Rail-Roads. Stiffness of Ropes 219 
 
 CHAPTER XX. 
 
 ON THE STRENGTH OF MATERIALS. 
 
 Difficulty of determining the Laws which govern the Strength of Materials. 
 Forces tending to separate the Parts of a Solid. Laws by which Solids 
 resist Compression. Euler's Theory. Transverse Strength of Solids. 
 Strength diminished by the Increase of Height. Lateral or Transverse 
 Strain. Limits of Magnitude. Relative Strength of small Animals 
 greater than large ones 229 
 
Vlli CONTENTS. 
 
 CHAPTER XXI. 
 
 ON BALANCES AND PENDULUMS. 
 
 Weight, Time. The Balance. Fulcrum. Centre of Gravity of. 
 Sensibility of. Positions of the Fulcrum. Beam variously constructed. 
 Troughton's Balance. Robinson's Balance. Rater's Balance. 
 Method of adjusting a Balance. Use of it. Precautions necessary. 
 Of Weights. Adjustment of. Dr. Black's Balance. Steelyard. 
 Roman Statera or Steelyard. Convenience of. C. Paul's Steelyard. 
 Chinese Steelyard. Danish Balance. Bent Lever Balance. Brady's 
 Balance. Weighing Mackine for Turnpike Roads. Instruments for 
 Weighing by Means of a Spring. Spring Steelyard. Sailer's Spring 
 Balance. Marriott's Dial Weighing Machine. Dynamometer. Com- 
 pensation Pendulums. Barton's Gridiron Pendulum. Table of linear 
 Expansion. Second Table. Harrison's Pendulum. Troughton's Pen- 
 dulum. Benzenberg's Pendulum. Ward's Compensation Pendulum. 
 Compensation Tube of Julien le Roy. Deparcieux's Compensation. 
 Kater's Pendulum. Reed's Pendulum. Ellicott's Pendulum. Mercurial 
 Pendulum. Graham's Pendulum. Compensation Pendulum of Wood 
 and Lead. Smeaton's Pendulum. Brown's Mode of Adjustment. .. 234 
 
THE 
 
 ELEMENTS OF MECHANICS. 
 
 CHAPTER I, 
 
 PROPERTIES OP MATTER MAGNITUDE IMPENETRABILITY 
 
 FIGURE FORCE. 
 
 (1.) PLACED in the material world, Man is continually 
 exposed to the action of an infinite variety of objects by 
 which he is surrounded. The body, to which the thinking 
 and living principles have been united, is an apparatus ex- 
 quisitely contrived to receive and to transmit these impres- 
 sions. Its various parts are organized with obvious reference 
 to the several external agents by which it is to be affected. 
 Each organ is designed to convey to the mind immediate 
 notice of some peculiar action, and is accordingly endued 
 with a corresponding susceptibility-. This adaptation of the 
 organs of sense to the particular influences of material agents, 
 is rendered still more conspicuous when we consider that, 
 however delicate its structure, each organ is wholly insensible 
 to every influence except that to which it appears to be 
 specially appropriated. The eye, so intensely susceptible of 
 impressions from light, is not at all affected by those of sound ; 
 while the fine mechanism of the ear, so sensitively alive to 
 every effect of the latter class, is altogether insensible to the 
 former. The splendor of excessive light may occasion blind- 
 ness, and deafness may result from the roar of a cannonade ; 
 but neither the sight nor the hearing can be injured by the 
 most extreme action of that principle which is designed to 
 affect the other. 
 
 Thus the organs of sense are instruments by which the 
 mind is enabled to determine the existence and the qualities 
 of external things. The effects which these objects produce 
 upon the mind through the organs, are called sensations, and 
 these sensations are the immediate elements of all human 
 
3 THE ELEMENTS OF MECHANICS. CHAP. I 
 
 knowledge. MATTER is the general name which has been 
 given to that substance, which, under forms infinitely various, 
 affects the senses. Metaphysicians have differed in defining 
 this principle. Some have even doubted of its existence. 
 But these discussions are beyond the sphere of mechanical 
 philosophy, the conclusions of which are in no wise affected 
 by them. Our investigations here relate, not to matter as an 
 abstract existence, but to those qualities which we discover in 
 it by the senses, and of the existence of which we are sure, 
 however the question as to matter itself may be decided. 
 When we speak of" bodies," we mean those things, whatever 
 they be, which excite in our minds certain sensations ; and 
 the powers to excite those sensations are called " properties," 
 or "qualities." 
 
 (2.) To ascertain, by observation, the properties of bodies, 
 is the first step towards obtaining a knowledge of nature. 
 Hence man becomes a natural philosopher the moment he 
 begins to feel and to perceive. The first stage of life is a 
 state of constant and curious excitement. Observation and 
 attention, ever awake, are engaged upon a succession of 
 objects new and wonderful. The large repository of the 
 memory is opened, and every hour pours into it unbounded 
 stores of natural facts and appearances, the rich materials of 
 future knowledge. The keen appetite for discovery, implant- 
 ed in the mind for the highest ends, continually stimulated 
 by the presence of what is novel, renders torpid every other 
 faculty, and the powers of reflection and comparison are lost 
 in the incessant activity and unexhausted vigor of observa- 
 tion. After a season, however, the more ordinary classes 
 of phenomena cease to excite by their novelty. Attention 
 is drawn from the discovery of what is new, to the examina- 
 tion of what is familiar. From the external world the mind 
 turns in upon itself, and the feverish astonishment of child- 
 hood gives place to the more calm contemplation of incipient 
 maturity. The vast and heterogeneous mass of phenomena 
 collected by past experience is brought under review. The 
 great work of comparison begins. Memory produces her 
 stores, and reason arranges them. Then succeed those first 
 attempts at generalization which mark the dawn of science 
 in the mind. 
 
 To compare, to classify, to generalize, seem to be instinc- 
 tive propensities peculiar to man. They separate him from 
 inferior animals by a wide chasm. It is to these powers that 
 
CHAP. I. MAGNITUDE. 3 
 
 all the higher mental attributes may be traced, and it is from 
 their right application that all progress in science must arise. 
 Without these powers, the phenomena of nature would 
 continue a confused heap of crude facts, with which 
 the memory might be loaded, but from which the intellect 
 would derive no advantage. Comparison and generalization 
 are the great digestive organs of the mind, by which only 
 nutrition can be extracted from this mass of intellectual food, 
 and without which observation the rrtfest extensive, and atten- 
 tion the most unremitting, can be productive of no real or 
 useful advancement in knowledge. 
 
 (3.) Upon reviewing those properties of bodies which the 
 senses most frequently present to us, we observe that very 
 few of them are essential to, and inseparable from, matter. 
 The greater number may be called particular or peculiar 
 qualities, being found in some bodies, but not in others. 
 Thus the property of attracting iron is peculiar to the load- 
 stone, and not observable in other substances. One body 
 excites the sensation of green, another of red, and a third 
 is deprived of all color. A few characteristic and essential 
 qualities are, however, inseparable from matter in whatever 
 state, or under whatever form it exist. Such properties alone 
 can be considered as tests of materiality. Where their pres- 
 ence is neither manifest to sense, nor demonstrable by reason, 
 there matter is not. The principal of these qualities are 
 magnitude and impenetrability. 
 
 (4.) Magnitude. Every body occupies space ; that is, it 
 has magnitude. This is a property observable by the senses in 
 all bodies which are not so minute as to elude them, and which 
 the understanding can trace to the smallest particle of matter. 
 It is impossible, by any stretch of imagination, even to con- 
 ceive a portion of matter so minute as to have no magnitude. 
 
 The quantity of space which a body occupies is sometimes 
 called its magnitude. In colloquial phraseology, the word 
 size is used to express this notion ; but the most correct term, 
 and that which we shall generally adopt, is volume. Thus 
 we say, the volume of the earth is so many cubic miles, the 
 volume of this room is so many cubic feet. 
 
 The external limits of the magnitude of a body are lines 
 and surfaces, lines being the limits which separate the several 
 surfaces of the same body. The linear limits of a body are 
 also called edges. Thus the line which separates the top of a 
 chest from one of its sides is called an edge. 
 
4 THE ELEMENTS OP MECHANICS. CHAP. I 
 
 The quantity of a surface is called its area, and the quan- 
 tity of a line is called its length. Thus we say, the area of a 
 field is so many acres, the length of a rope is so many yards. 
 The word " magnitude" is, however, often used indifferently 
 for volume, area, and length. If the objects of investigation 
 were of a more complex and subtle character, as in metaphys- 
 ics, this unsteady application of terms might be productive 
 of confusion, and even of error ; but in this science, the mean- 
 ing of the term is evident, from the way in which it is ap- 
 plied, and no inconvenience is found to arise. 
 
 (5.) Impenetrability. This property will be most clearly 
 explained by defining the positive quality from which it lakes 
 its name, and of which it merely signifies the absence. A 
 substance would be penetrable if it were such as to allow 
 another to pass through the space which it occupies, without 
 disturbing its component parts. Thus, if a comet, striking 
 the earth, could enter it at one side, and, passing through it, 
 emerge from the other without separating or deranging any 
 bodies on or within the earth, then the earth would be pene- 
 trable by the comet. When bodies are said to be impenetra- 
 ble, it is therefore meant that one cannot pass through another 
 without displacing some or all of the component parts of that 
 other. There are many instances of apparent penetration ; 
 but in all these, the parts of the body which seem to be pene- 
 trated are displaced. Thus, if tV.e point of a needle be plung- 
 ed in a vessel of water, all the water which previously filled 
 the space into which the needle enters will be displaced, and 
 the level of the water will rise in the vessel to the same height 
 as it would by pouring in so much more water as would fill 
 the space occupied by the needle. 
 
 (6.) Figure. If the hand be placed upon a solid body, 
 we become sensible of its impenetrability, by the obstruction 
 which it opposes to the entrance of the hand within its di- 
 mensions. We are also sensible that this obstruction com- 
 mences at certain places; that it has certain determinate 
 limits ; that these limitations are placed in certain directions 
 relatively to each other. The mutual relation which is found 
 to subsist between these boundaries of a body, gives us the 
 notion of its figure. The figure and volume of a body should 
 be carefully distinguished. Each is entirely independent 
 of the other. Bodies having very different volumes may have 
 the same figure ; and in like manner bodies differing in fig- 
 ure may have the same volume. The figure of a body is 
 
CHAP. I. FORCE. 5 
 
 what, in popular language, is called its shape, or form. The 
 volume of a body is that which is commonly called its size. 
 It will hence be easily understood, that one body (a globe, 
 for example) may have ten times the volume of another (globe), 
 and yet have the same figure ; and that two bodies (as a die 
 and a globe) may have jigvrts altogether different, and yet have 
 equal volume*. What we have here observed of volumes will 
 also be applicable to lengths and areas. The arc of a circle 
 and a straight line may have the same length, although they 
 have different figures ; and, on the other hand, two arcs of 
 different circles may have the same figure, but very unequal 
 lengths. The surface of a ball is curved, that of the table 
 plane ; and yet the area of the surface of the ball may be 
 equal to that of the table. 
 
 (7.) Atoms Molecule*. Impenetrability must not be con- 
 founded with inseparability. Every body which has been 
 brought under human observation is separable into parts , 
 and these parts, however small, are separable into others still 
 more minute. To this process of division no practical limit 
 has ever been found. Nevertheless, many of the phenomena 
 which the researches of those who have successfully examined 
 the laws of nature have developed, render it highly probable 
 that all bodies are composed of elementary parts which are 
 indivisible and unalterable. The component parts, which 
 may be called atoms, are so minute as altogether to elude 
 the senses, even when improved by the most powerful aids 
 of art. The word molecule is often used to signify component 
 parts of a body so small as to escape sensible observation, 
 but not ultimate atoms, each molecule being supposed to be 
 {ormed of several atoms, arranged according to some deter- 
 minate figure. Particle is used also to express small compo- 
 nent parts, but more generally is applied to those which are 
 not too minute to be discoverable by observation. 
 
 (8.) force. If the particles of matter were endued with 
 no property in relation to one another, except their mutual 
 impenetrability, the universe would be like a mass of sand, 
 without variety of state or form. Atoms, when placed in 
 juxtaposition, would neither cohere, as in solid bodies, nor repel 
 each other, as in aeriform substances. We find, on the other 
 hand, that, in some cases, the atoms which compose bodies 
 are not simply placed together, but a certain effect is mani- 
 fested in their strong coherence. If they were merely placed 
 in juxtaposition, their separation would be effected as easily 
 1 * 
 
O THE ELEMENTS OF MECHANICS. CHAP. I. 
 
 3jj* '-. . 
 
 as any component particle could be removed from one 
 place to another. Take a piece of iron, and attempt to sep- 
 arate its parts : the effort will be strongly resisted, and it will 
 be a matter of much greater facility to remove the whole 
 mass. It appears, therefore, that, in such cases, the parts 
 which are in juxtaposition cohere, and resist their mutual 
 separation. This effect is denominated force ; and tfce con- 
 stituent atoms are said to cohere with a greater or less degree 
 of force, according as they oppose a greater or less resistance 
 to their mutual separation. 
 
 The coherence of particles in juxtaposition is an effect 
 of the same class as the mutual approach of particles placed 
 at a distance from each other. It is not difficult to perceive 
 that the same influence which causes the bodies A and B to 
 approach each other, when placed at some distance asunder, 
 will, when they unite, retain them together, and oppose a resist- 
 ance to their separation. Ilejice this effect of the mutual ap- 
 proximation of bodies towards each other is also called fore e. 
 
 Force is generally denned to be " whatever produces or 
 opposes the production of motion in matter." In this sense, 
 it is a name for the unknown cause of a known effect. It 
 would, however, be more philosophical to give the name, not 
 to the cause, of which we are ignorant, but to the effect, of 
 which we have sensible evidence. To observe and to classify 
 is the whole business of the natural philosopher. When 
 causes are referred to, it is implied, that effects of the same 
 class arise from the agency of the same cause. However 
 probable this assumption may be, it is altogether unnecessary. 
 All the objects of science, the enlargement of mind, the ex- 
 tension and improvement of knowledge, the facility of its 
 acquisition, are obtained by generalization alone, and no 
 good can arise from tainting our conclusions with the possible 
 errors of hypotheses. 
 
 It may be here, once for all, observed, that the phraseology 
 of causation and hypotheses has become so interwoven with 
 the language of science, that it is impossible to avoid the fre- 
 quent use of it. Thus we say, " the magnet attracts iron ;" 
 the expression attract intimating the cause of the observed 
 effect. In such cases, however, we must be understood 
 to mean the effect itself, finding it less inconvenient to con- 
 tinue the use of the received phrases, modifying their signifi- 
 cation, than to introduce new ones. 
 
 Force, when manifested by the mutual approach or cohe- 
 
CHAP. II. PROPERTIES OF MATTER. 7 
 
 sion of bodies, is also called attraction, and it is variously 
 denominated, according to the circumstances under which it 
 is observed to act. Thus the force which holds together the 
 atoms of solid bodied is called cohesive attraction. The force 
 which draws bodies to the surface of the earth, when placed 
 above it, is called the attraction of gravitation. The force 
 which is exhibited by the mutual approach, or adhesion of the 
 loadstone and iron, is called magnetic attraction; and so on. 
 
 When force is manifested by the remotion of bodies from 
 each other, it is called repnhion. Thus, if a piece of glass, 
 having been briskly rubbed with a silk handkerchief, touch, 
 successively, two feathers, these feathers, if brought near 
 each other, will move asunder. This effect is called repul- 
 sion, and the feathers are said to repel each other. 
 
 (9.) The influence which forces have upon the form, state, 
 arrangement and motions of material substances, is the 
 principal object of physical science. In its strict sense, ME- 
 CHANICS is a term of very extensive signification. According 
 to the more popular usage, however, it has been generally 
 applied to that part of physical science which includes the 
 investigation of the phenomeni of motion and rest, pressure, 
 and other effects developed by the mutual action of solid 
 masses. The consideration of similar phenomena, exhibited 
 in bodies of the liquid form, is consigned to HYDROSTATICS, 
 and that of aeriform fluids to PNEUMATICS. 
 
 CHAPTER II. 
 
 DIVISIBILITY POROSITY DENSITY COMPRESSIBILITY ELAS- 
 TICITY DILATABILITY. 
 
 (10.) BESIDES the qualities, magnitude and impenetra- 
 bility, there .are several other general properties of bodies 
 contemplated in mechanical philosophy, and to which we 
 shall have frequent occasion to refer. Those which we shall 
 notice in the present chapter are, 
 
 1. Divisibility. 
 
 2. Porosity Density. 
 
 3. Compressibility Elasticity. 
 
 4. Dilatability. 
 
 (11.) Divisibility. Observation and experience prove that 
 
8 THE ELEMENTS OF MECHANICS. CHAP. II. 
 
 all bodies of sensible magnitude, even the most solid, consist 
 of parts which are separable. To the practical subdivision 
 of matter there seems to be no assignable limit. Numerous 
 examples of the division of matter, to a degree almost ex- 
 ceeding belief, may be found in experimental inquiries insti- 
 tuted in physical science ; the useful arts furnish many in- 
 stances not less striking ; but, perhaps, the most conspicuous 
 proofs which can be produced, of the extreme minuteness 
 of which the parts of matter are susceptible, arise from the 
 consideration of certain parts of the organized world. 
 
 (12.) The relative places of stars in the heavens, as seen 
 in the field of view of a telescope, are marked by fine lines 
 of wire placed before the eye-glass, and which cross each 
 other at right angles. The stars appearing in the telescope 
 as mere lucid points without sensible magnitude, it is neces- 
 sary that the wires which mark their places should have a 
 corresponding tenuity. But these wires, being magnified by 
 the eye-glass, would have an apparent thickness, which 
 would render them inapplicable to this purpose, unless their 
 real dimensions were of a most uncommon degree of minute- 
 ness. To obtain wire for this purpose, Dr. Wollaston invent- 
 ed the following process : A piece of fine platinum wire, a 
 b, is extended along the axis of a cylindrical mould. A B,^. 
 1. Into this mould, at A, molten silver is poured. Since 
 the heat necessary for the fusion of platinum is much greater 
 than that which retains silver in the liquid form, the wire a b 
 remains solid, while the mould A B is filled with the silver. 
 When the metal has become solid by being cooled, and has 
 been removed from the mould, a cylindrical bar of silver is 
 obtained, having a platinum wire in its axis. This bar is 
 then wire-drawn, by forcing it successively through holes C, 
 D, E, F, G, H, diminishing in magnitude, the first hole 
 being a little less than the wire at the beginning of the 
 process. By these means the platinum a b is wire-drawn at 
 the same time, and in the same proportion with* the silver, so 
 that, whatever be the original proportion of the thickness of 
 the wire a b to that of the mould A B, the same will be the 
 proportion of* the platinum wire to the whole at the several 
 thicknesses C, D, &/c. If we suppose the mould A B to be 
 ten times the thickness of the wire a b, then the silver wire, 
 throughout the whole process, will be ten times the thickness 
 of the platinum wire which it includes within it. The silver 
 wire may be drawn to a thickness not exceeding the 300th of 
 
CHAP. II. DIVISIBILITY. 9 
 
 an inch. The platinum will thus not exceed the 3000th of an 
 inch. The wire is then dipped in nitric acid, which dissolves 
 the silver, but leaves the platinum solid. By this method 
 Dr. Wollaston succeeded in obtaining wire, the diameter 
 of which did not exceed the 18,000th of an inch. A quantity 
 of this wire, equal in bulk to a common die used in games 
 of chance, would extend from Paris to Rome. 
 
 (13.) Newton succeeded in determining the thickness of 
 very thin laminae of transparent substances by observing the 
 colors which they reflect. A soap bubble is a thin shell 
 of water, and is observed to reflect different colors from dif- 
 ferent parts of its surface. Immediately before the bubble 
 bursts, a black spot may be observed near the top. At 
 this part the thickness has been proved not to exceed the 
 2,500,000th of an inch. 
 
 The transparent wings of certain insects are so attenuated 
 in their structure, that 50,000 of them placed over each other 
 would not form a pile a quarter of an inch in height. 
 
 (14.) In the manufacture of embroidery, it is necessary to 
 obtain very fine gilt silver threads. To accomplish this, a 
 cylindrical bar of silver, weighing 360 ounces, is covered 
 with about two ounces of gold. This gilt bar is then wire- 
 drawn, as in the first example, until it is reduced to a thread 
 so fine that 3400 feet of it weigh less than an ounce. The 
 wire is then flattened by passing it between rollers under 
 a severe pressure a process which increases its length, so 
 that about 4000 feet shall weigh one ounce. Hence one foot 
 will weigh the 4000th part of an ounce. The proportion of 
 the gold to the silver in the original bar was that of 2 to 360, 
 or 1 to 180. Since the same proportion is preserved after the 
 bar has been wire-drawn, it follows that the quantity of gold 
 which covers one foot of the fine wire is the 180th part of the 
 4000th of an ounce ; that is, the 720,000th part of an ounce. 
 
 The quantity of gold which covers one inch of this wire 
 will be twelve times less than that which covers one foot. 
 Hence this quantity will be the 8,640,000th part of an ounce. 
 If this inch be again divided into 100 equal parts, every part 
 will be distinctly visible without the aid of microscopes. 
 The gold which covers this small but visible portion is the 
 864,000,000th part of an ounce. But we may proceed even 
 further ; this portion of the wire may be viewed by a micro- 
 scope which magnifies 500 times, so that the 500th part 
 of it will thus become visible. In this manner, therefore, 
 
10 THE ELEMENTS OF MECHANICS. CHAP. II. 
 
 an ounce of gold may be divided into 432,000,000,000 parts. 
 Each of these parts will possess all the characters and quali- 
 ties which are found in the largest masses of the metal. It 
 retains its solidity, texture, and color ; it resists the same 
 agents, and enters into combination with the same substances. 
 If the gilt wire be dipped in nitric acid, the silver within the 
 coating will be dissolved, but the hollow tube of gold which 
 surrounded it will still cohere and remain suspended. 
 
 (15.) The organized world offers still more remarkable 
 examples of the inconceivable subtilty of matter. 
 
 The blood which flows in the veins of animals is not, as it 
 seems, an uniformly red liquid. It consists of small red 
 globules, floating in a transparent fluid called scrum. In 
 different species these globules differ both in figure and 
 in magnitude. ^In man and all animals which suckle their 
 young, they are perfectly round or spherical. In birds an4 
 fishes, they are of an oblong spheroidal form. In the human 
 species, the diameter of the globules is about the 4000th 
 of an inch. Hence it follows, that in a drop of blood which 
 would remain suspended from the point of a fine needle, 
 there must be about a million of globules. 
 
 Small as these globules are, the animal kingdom presents 
 beings whose whole bodies are still more minute. Animal- 
 cules have been discovered, whose magnitude is such, that 
 a million of them does not exceed the bulk of a grain of 
 sand ; and yet each of these creatures is composed of mem- 
 bers as curiously organized as those of the largest species ; 
 they have <life and spontaneous motion, and are endued with 
 sense and instinct. In the liquids in which they live, they 
 are observed to move with astonishing speed and activity ; nor 
 are their motions blind and fortuitous, but evidently governed 
 by choice, and directed to an end. They use food and drink, 
 from which they derive nutrition, and are therefore furnished 
 with a digestive apparatus. They have great muscular power, 
 and are furnished with limbs and muscles of strength and flexi- 
 bility. They are susceptible of the same appetites, and obnox- 
 ious to the same passions, the gratification of which is attend- 
 ed with the same results as in our own species. Spallanzani 
 observes, that certain animalcules devour others so voraciously, 
 that they fatten and become indolent and sluggish by over- 
 feeding. After a meal of this kind, if they be confined in 
 distilled water, so as to be deprived of all food, their condition 
 becomes reduced ; they regain their spirit and activity, and 
 
CHAP. II. ULTIMATE ATOMS. 11 
 
 amuse themselves in the pursuit of the more minute animals, 
 which are supplied to them ; they swallow these without 
 depriving them of life, for, by the aid of the microscope, 
 the one has been observed moving within the body of the 
 other. These singular appearances are not matters of idle 
 and curious observation. They lead us to inquire what 
 parts are necessary to produce such results. Must we not 
 conclude that these creatures have heart, arteries, veins, mus- 
 cles, sinews, tendons, nerves, circulating fluids, and all the 
 concomitant apparatus of a living organized body ? And 
 if so, how inconceivably minute must those parts be ! If a 
 globule of their blood bears the same proportion to their 
 whole bulk as a globule of our blood bears to our magnitude, 
 what powers of calculation can give an adequate notion of its 
 minuteness ? 
 
 (16.) These and many other phenomena observed in the 
 immediate productions of nature, or developed by mechanical 
 and chemical processes, prove that the materials of which 
 bodies are formed are susceptible of minuteness which in- 
 finitely exceeds the powers of sensible observation, even when 
 those powers have been extended by all the aids of science. 
 Shall we then conclude that matter is infinitely divisible, 
 and that there are no original constituent atoms of determi- 
 nate magnitude and figure at which all subdivision must 
 cease? Such an inference would be unwarranted, even had 
 we no other means of judging the question, except those 
 of direct observation ; for it would be imposing that limit 
 on the works of nature which she has placed upon our powers 
 of observing them. Aided by reason, however, and a due 
 consideration of certain phenomena which come within our 
 immediate powers of observation, we are frequently able to 
 determine other phenomena which are beyond those powers. 
 The diurnal motion of the earth is not perceived by us, be 
 cause all things around us participate in it, preserve their 
 relative position, and appear to be c.t rest. But reason tells 
 us that such a motion must produce the alternations of day 
 and night, and the rising and setting of all the heavenly 
 bodies appearances which are plainly observable, and which 
 betray the cause from which they arise. Again, we cannot 
 place ourselves at a distance from the earth, and behold 
 the axis on which it revolves, and observe its peculiar obli- 
 quity to the orbit in which the earth moves ; but we see 
 and feel the vicissitudes of the seasons an effect which is the 
 
12 THE ELEMENTS OF MECHANICS. CHAP. II. 
 
 immedi te consequence of that inclination, and by which we 
 are able to detect it. 
 
 (17.) So it is in the present case. Although we are 
 unable by direct observation to prove the existence of con- 
 stituent material atoms of determinate figure, yet there are 
 many observable phenomena which render their existence 
 in the highest degree probable, if not morally certain. The 
 most remarkable of this class of effects is observed in the 
 crystallization of salts. When salt is dissolved in a sufficient 
 quantity of pure water, it mixes with the water in such a 
 manner as wholly to disappear to the sight and touch, 
 the mixture being one uniform transparent liquid, like the 
 water itself, before its union with the salt. The presence 
 of the salt in the water may, however, be ascertained by 
 weighing the mixture, which will be found to exceed the 
 original weight of the water by the exact amount of the 
 weight of the salt. It is a well-known fact, that a certain 
 degree of heat will convert water into vapor, and that the 
 same degree of heat does not effect any change on the form 
 of salt. The mixture of salt and water being exposed to 
 this temperature, the water will gradually evaporate, disen- 
 gaging itself from the salt with which it has been combined. 
 When so much of the water has evaporated, that what re- 
 mains is insufficient to keep in solution the whole of the salt, 
 a part of it thus disengaged from the water will return to the 
 solid state. The saline particles will not in this case collect 
 in irregular solid molecules, but will exhibit themselves in 
 particles of regular figures, terminated by plane surfaces, 
 the figures being always the same for the same species of salt, 
 but different for different species. There are several cir- 
 cumstances in the formation of these crystals which merit 
 attention. 
 
 If one of the crystals be detached from the others, and the 
 progress of its formation observed, it will be found gradually 
 to increase, always preserving its original figure. Since its 
 increase must be caused by the continued accession of saline 
 particles, disengaged by the evaporation of the water, it fol- 
 lows that these particles must be so formed, that, by attaching 
 themselves successively to the crystal, they maintain the reg- 
 ularity of its bounding planes, and preserve their mutual in- 
 clinations unvaried. 
 
 Suppose a crystal to be taken from the liquid during the 
 process of crystallization, and a piece broken from it so as to 
 
CHAP. II. CRYSTALLIZATION. 13 
 
 destroy the regularity of its form ; if the crystal thus broken 
 be restored to the liquid, it will be observed gradually to 
 resume its regular form, the atoms of salt successively dis- 
 missed by the vaporizing water filling up the irregular cavi- 
 ties produced by the fracture. Hence it follows, that the 
 saline particles which compose the surface of the crystal, 
 and those which form the interior of its mass, are similar, 
 and exert similar attractions on the atoms disengaged by the 
 water. 
 
 All these details of the process of crystallization are very 
 evident indications of a determinate figure in the ultimate 
 atoms of the substances which are crystallized. But besides 
 the substances which are thus reduced by art to the form 
 of crystals, there are larger classes which naturally exist in 
 that state. There are certain planes, called planes of cleav- 
 age, in the directions of which natural crystals are easily 
 divided. These planes, in substances of the same kind, 
 always have the same relative position, but differ in different 
 substances. The surfaces of the planes of cleavage are quite 
 invisible before the crystal is divided ; but when the parts 
 are separated, these surfaces exhibit a most intense polish, 
 which no effort of art can equal. 
 
 We may conceive crystallized substances to be regular 
 mechanical structures formed of atoms of a certain figure, 
 on which the figure of the whole structure must depend. The 
 planes of cleavage are parallel to the sides of the constituent 
 atoms ; and their directions, therefore, form so many condi- 
 tions for the determination of its figure. The shape of the 
 atoms being thus determined, it is not difficult to assign all 
 the various ways in which they may be arranged, so as to 
 produce figures which are accordingly found to correspond 
 with the various forms of crystals of the same substance. 
 
 (18.) When these phenomena are duly considered and 
 compared, little doubt can remain that all substances suscep- 
 tible of crystallization, consist of atoms of determinate figure. 
 This is the case with all solid bodies whatever, which have 
 come under scientific observation, for they have been sever- 
 ally found in or reduced to a crystallized form. Liquids 
 crystallize in freezing ; and if aeriform fluids could by any 
 means be reduced to the solid form, they would probably also 
 manifest the same effect. Hence it appears reasonable to 
 presume, that all bodies are composed of atoms ; that the 
 different qualities with which we find different substances 
 
14 THE ELEMENTS OF MECHANIC'S. CHAP. II. 
 
 endued, depend on the magnitude and figure of these atoms; 
 that these atoms are indestructible and immutaHo by any 
 natural process, for we find the qualities which depend on 
 them unchangeably the same under all the influences to 
 which they have been submitted since their creation ; that 
 these atoms are so minute in their magnitude, that they can- 
 not be observed by any means which human art has yet con- 
 trived ; but still that magnitudes can be assigned which they 
 do not exceed. 
 
 It is proper, however, to observe here, that the various 
 theorems of mechanical science do not rest upon any hypoth- 
 esis concerning these atoms as a basis. They are not infer- 
 red from this or any other supposition, and therefore their 
 truth would not be in anywise disturbed, even though it 
 should be established that matter is physically divisible in 
 infinitum. The basis of mechanical science is observed facts ; 
 and since the reasoning is demonstrative, the conclusions 
 have the same degree of certainty as the facts from which 
 they are deduced. 
 
 (19.) Porosity. The volume of a body is the quantity 
 of space included within its external surfaces. The mass 
 of a body is the collection of atoms or material particles 
 of which it consists. Two atoms or particles are said to be 
 in contact, when they have approached each other until ar- 
 rested by their mutual impenetrability. If the component 
 particles of a body were in contact, the volume would be 
 completely occupied by the mass. But this is not the case. 
 We shall presently prove, that the component particles of no 
 known substance are in absolute contact. Hence it follows 
 that, the volume consists partly of material particles, and 
 partly of interstitial spaces, which spaces are either absolute- 
 ly void and empty, or filled by some substance of a different 
 species from the body in question. These interstitial spaces 
 are called pores. 
 
 In bodies which are constituted uniformly throughout their 
 entire dimensions, the component particles and the pores are 
 uniformly distributed through the volume ; that is, a given 
 space in one part of the volume will contain the same quantity 
 of matter and the same quantity of porqs as an equal space in 
 another part. 
 
 (20.) The proportion of the quantity of matter to the 
 magnitude is called the density. Thus if, of two substances, 
 one contains in a given space twice as much matter as the 
 
CHAP. II. POROSITY. 15 
 
 other, it is said to be " twice as dense." The density of bodies 
 is, therefore, proportionate to the closeness or proximity of 
 their particles ; and it is evident, that the greater the density, 
 the less will be the porosity. 
 
 The pores of a body are frequently filled with another 
 body of a more subtile nature. If the pores of a body on the 
 surface of the earth, and exposed to the atmosphere, be great- 
 er than the atoms of air, then the air will pervade the pores. 
 This is found to be the case of many sorts of wood which 
 have open grains. If a piece of such wood, or of chalk, 
 or of sugar, be pressed to the bottom of a vessel of water, 
 the air which fills the pores will be observed to escape in 
 bubbles, and to rise at the surface, the water pervading the 
 pores, and taking its place. 
 
 If a tall vessel or tube, having a. wooden bottom, be filled 
 with quicksilver, the liquid metal will be forced by its own 
 weight through the pores of the wood, and will be seen es- 
 caping in a silver shower from the bottom. 
 
 (21.) The process of filtration, in the arts, depends on 
 the presence of pores of such a magnitude as to allow a pas- 
 sage to the liquid, but to refuse it to those impurities from 
 which it is to be disengaged. Various substances are used 
 as filtres ; but, whatever be used, this circumstance should 
 always be remembered, that no substance can be separated 
 from a liquid by filtration, except one whose particles are 
 larger than those of the liquid. In general, filtres are used 
 to separate solid impurities from a liquid. The most ordinary 
 filtres are soft stone, paper and charcoal. 
 
 (22.) All organized substances in the animal and vegeta- 
 ble kingdoms are, from their very natures, porous in a high 
 degree. Minerals are porous in various degrees. Among 
 the siliceous stones is one called kydropkme tt which manifests 
 its porosity in a very remarkable manner. The stone, in its 
 ordinary state, is semi-transparent. If, however, it be plung- 
 ed in water, when it is withdrawn, it is as translucent as glass. 
 The pores, in this case, previously filled with air, are pervaded 
 by the water, between which and the stone there subsists a 
 physical relation, by which the one renders the other perfectly 
 transparent. 
 
 Larger mineral masses exhibit degrees of porosity not less 
 striking. Water percolates through the sides and roofs of 
 caverns and grottoes, and, being impregnated with calcareous 
 
 
16 THE ELEMENTS OF MECHANICS. CHAP. II. 
 
 and other earths, forms stalactites, or pendent protuberances, 
 which present a curious appearance. 
 
 (23.) Compressibility. That quality, in virtue of which 
 a body allows its volume to be diminished without diminish- 
 ing its mass, is called compressibility. This effect is produced 
 by bringing the constituent particles more. close together, and 
 thereby increasing the density and diminishing the pores. 
 This effect may be produced in several ways; but the name 
 " compressibility" is only applied to it when it is caused by 
 the agency of mechanical force, as by pressure or percussion. 
 
 All known bodies, whatever be their nature, are capable 
 of having their dimensions reduced without diminishing 
 their mass ; and this is one of the most conclusive proofs that 
 all bodies are porous, or that the constituent atoms are not in 
 contact;,, for the space by which the volume maybe diminish- 
 ed must, before the diminution, consist of pores. 
 
 (24.) Some bodies, when compressed by the agency of 
 mechanical force, will resume their former dimensions with 
 a certain force when relieved from the operation of the force 
 which has compressed them. This property is called elastici- 
 ty ; and it follows, from this definition, that all elastic bodies 
 must be compressible, although the converse is not true, com- 
 pressibility riot necessarily implying elasticity. 
 
 (25.) Dilatability . This quality is the opposite of com- 
 pressibility. It is the capability observed in bodies to have 
 their volume enlarged without increasing their mass. This 
 effect may be produced in several ways. In ordinary circum- 
 stances, a body may exist under the constant action of a 
 pressure by which its volume and density are determined. It 
 may happen, that, on the occasional removal of that pressure, 
 the body will dilate by a quality inherent in its constitution. 
 This is the case with common air. Dilatation may also be 
 the effect of heat, as will presently appear. 
 
 The several qualities of bodies which we have noticed in 
 this chapter, when viewed in relation to each other, present 
 many circumstances worthy of attention. 
 
 (26.) It is a physical law, to which there is no real ex- 
 ception, that an increase in the temperature, or degree of 
 heat by which a body is affected, is accompanied by an in- 
 crease of volume ; and that a diminution of temperature is 
 accompanied by a diminution of volume. The apparent ex- 
 ceptions to this law will be noticed and explained in our 
 
CHAP. II. 
 
 DILATABILITY. 17 
 
 
 treatise on HEAT. Hence it appears that the reduction of 
 temperature is an effect which, considered mechanically, is 
 equivalent to compression or condensation, since it. diminishes 
 the volume without altering; the mass ; and since this is an 
 effect of which all bodies whatever are susceptible, it follows 
 that all bodies whatever have pores. (23.) 
 
 The fact, that the elevation of temperature produces an 
 increase of volume, is manifested by numerous experiments. 
 
 (37.) If a flaccid bladder be tied at the mouth, so as 
 to stop the passage of air, and be then held before a fire, 
 it will gradually swell, and assume the appearance of being 
 fully inflated. The small quantity of air contained in the 
 bladder is, in this case, so much dilated by the heat, that it 
 occupies a considerably increased space, and fills the bladder, 
 of which it before -only occupied a small part. When the 
 I ladder is removed from the fire, and allowed to resume its 
 former temperature, the air returns to its former dimensions, 
 and the bladder becomes again flaccid. 
 
 (28.) Let A B, fig. 2. be a glass tube, with a bulb at the 
 end A ; and let the bulb A, and a part of the tube, be filled 
 with any liquid, colored so as to be visible. Let C be the 
 level of the liquid in the tube. If the bulb be now exposed 
 to heat, by being plunged in hot water, the level of the liquid 
 C will rapidly rise towards B. This effect is produced by the 
 dilatation of the liquid in the bulb, which filling a greater 
 space, a part of it is forced into the tube. This experiment 
 may easily be made with a common glass tube and a little 
 port wine. 
 
 Thermometers are constructed on this principle, the rise 
 of the liquid in the tube being used as an indication of the 
 degree of heat which causes it. A particular account of 
 these useful instruments will be found in our treatise on HEAT. 
 
 (29.) The change , of dimension of solids produced by 
 changes of temperature, being much less than that of bodies 
 in the liquid or aeriform state, is not so easily observable. 
 A remarkable instance occurs in the process of shoeing the 
 wheels of carriages. The rim of iron with which the wheel 
 is to be bound, is made, in the first instance, of a diameter 
 somewhat less than that of the wheel ; but, being raised 
 by the application of fire to a very high temperature, its 
 volume receives such an increase, that it will be sufficient 
 to embrace and surround the wheel. When placed upon the 
 wheel, it is cooled, and, suddenly contracting its dimensions, 
 2* ' 
 
18 THE ELEMENTS OF MECHANIC'S. CHAP. 11. 
 
 binds the parts of the wheel firmly together, and becomes 
 securely seated in its place upon the face of the fellies. 
 
 (30.) It. frequently happens that the stopper of a glass 
 bottle or decanter becomes fixed in its place so firmly, that 
 the exertion of force sufficient to withdraw it would endanger 
 the vessel. In this case, if a cloth wetted with hot water 
 be applied to the neck of the bottle, the glass will expand, 
 and the neck will be enlarged, so as to allow the stopper 
 to be easily withdrawn. 
 
 (31.) The contraction of metal consequent upon change 
 of temperature has been applied some time ago in Paris 
 to restore the walls of a tottering building to their proper 
 position. In the Conservatoire, dts Arts ct Meticrcs, the walls 
 of a part of the building were forced out of the perpendicular 
 by the weight of the roof, so that each wall was leaning out- 
 wards. M. Molard conceived the notion of applying the irre- 
 sistible force with which metals contract in cooling, to draw 
 the walls together. Bars of iron were placed in parallel 
 directions across the building, and at right angles to the di- 
 rection of the walls. Being passed through the walls, nuts 
 were screwed on their ends, outside the building. Every 
 alternate bar was then heated by lamps, and the nuts screw- 
 ed close to the walls. The bars were then cooled, and the 
 lengths being diminished by contraction, the nuts on their 
 extremities were drawn together, and with them the walls 
 were drawn through an equal space. The same process was 
 repeated with the intermediate bars, and soon alternately until 
 the walls were brought into a perpendicular position. 
 
 (32 ) Since there is a continual change of temperature 
 in all bodies on the surface of the globe, it follow r s, that there 
 is also a continual change of magnitude. The substances 
 which surround us are constantly swelling and contracting 
 under the vicissitudes of heat and cold. They grow smaller 
 in winter, and dilate in summer. They swell their bulk 
 on a warm day, and contract it on a cold one. These curi- 
 ous phenomena are not noticed, only because our ordinary 
 means of observation are not sufficiently accurate to appre- 
 ciate them. Nevertheless, in some familiar instances the 
 effect is very obvious. In warm weather, the flesh swells, 
 the vessels appear filled, the hand is plump, and the skin 
 distended. In cold weather, when the body has been expos- 
 ed to the open air, the flesh appears to contract, the vessels 
 shrink, and the skin shrivels. 
 
CHAP. II. 
 
 COMPRESSIBILITY. 19 
 
 (33.) The phenomena attending change of temperature 
 are conclusive proofs of the universal porosity of material sub- 
 stances, hut they are not the only proofs. Many substances 
 admit of compression by the mere agency of mechanical 
 force. 
 
 Let a small piece of cork be placed floating on the surface 
 of water in a basin or other vessel, and an empty glass goblet 
 be inverted over the cork, so that its edge just meets the 
 water. A portion of air will then be confined in the goblet, 
 and detached from the remainder of the atmosphere. If the 
 goblet be now pressed downwards, so as to be entirely im- 
 mersed, it will be observed, that, the water will not fill it, 
 being excluded by the impenetrability of the air enclosed in 
 it. This experiment, therefore, is decisive of the fact, that 
 air, one of the most subtile and attenuated substances we 
 know of, possesses the quality of impenetrability. It abso- 
 lutely excludes any other body from the space which it occu- 
 pies at any given moment. 
 
 But although the water does not fill the goblet, yet if the 
 position of the cork which floats upon its surface be noticed, 
 it will be found that the level of the water within has risen 
 above its edge or rim. In fact, the water has partially filled 
 the goblet, and the air has been forced to contract its dimen- 
 sions. This effect is produced by the pressure of the incum- 
 bent water forcing the surface in the goblet against the air, 
 which yields until it is so far compressed that it acquires a 
 force able to withstand this pressure. Thus it appears that 
 air is capable of being reduced in its dimensions by mechani- 
 cal pressure, independently of the agency of heat. It is 
 compressible. 
 
 That this effect is the consequence of the pressure of the 
 liquid, will be easily made manifest by showing that, as the 
 pressure is increased, the air is proportionally contracted in 
 its dimensions ; and as it is diminished, the dimensions are, 
 on the other hand, enlarged. If the depth of the goblet 
 in the water be increased, the cork will be seen to rise in 
 it, showing that the increased pressure, at the greater depth, 
 causes the air in the goblet to be more condensed. If, 
 on the other hand, the goblet be raised toward the sur- 
 face, the cork will be observed to descend toward the edge, 
 showing that as it is relieved from the pressure of the 
 liquid, the air gradually approaches to its primitive dimen- 
 sions. 
 
20 THE ELEMENTS OF MECHANICS. CHAP. II. 
 
 (34.) These phenomena also prove, that air has the prop- 
 erty of elasticity. If it wore simply compressible, and not 
 elastic, it would retain the dimensions to which it was reduced 
 by the pressure of the liquid ; but this is not found to be 
 the result. As the compressing force is diminished, so in 
 the same proportion does the air, by its elastic virtue, exert a 
 force by which it resumes its former dimensions. 
 
 That it is the air alone which excludes the water from the 
 goblet, in the preceding experiments, can easily be proved. 
 When the goblet is sunk deep in the vessel of water, let it be 
 inclined a little to one side until its mouth is presented to- 
 wards the side of the vessel ; let this inclination be so regu- 
 lated, that the surface of the water in the goblet shall just reach 
 its edge. Upon a slight increase of inclination, air will be 
 observed to escape from the goblet, and to rise in bubbles 
 to the surface of the water. If the goblet be then restored 
 to its position, it will be found that the cork will rise higher 
 in it than before the escape of the air. The water in this 
 case rises, and fills the'space which the air allowed to escape 
 has deserted. The same process may be repeated until all the 
 air has escaped, and the!) the goblet will be completely filled 
 by the water. 
 
 (35.) Liquids are compressible by mechanical force in so 
 slight a degree, that they are considered, in all hydrostatical 
 treatises, as incompressible fluids. They are, however, not 
 absolutely incompressible, but yield slightly to very intense 
 pressure. The question of the compressibility of liquids was 
 raised at a remote period in the history of science. Nearly 
 two centuries ago, an experiment was instituted at the Acad- 
 emy del Oimcnto in Florence, to ascertain whether water be 
 compressible. With this view, a hollow ball of gold was 
 filled with the liquid, and the aperture exactly and firmly 
 closed. The globe was then submitted to a very severe 
 pressure, by which its figure was slightly changed. Now 
 it is proved in geometry, that a globe has this peculiar prop- 
 erty, that any change whatever in its figure must necessarily 
 diminish its volume or contents. Hence it was inferred, that 
 if the water did not issue through the pores of the gold, or 
 burst the globe, its compressibility would be established. The 
 result of the experiment was, that the water did ooze through 
 the pores, and covered the surface of the globe, presenting 
 the appearance of dew, or of steam cooled by the metal. But 
 this experiment was inconclusive. It is quite true, that if 
 

 CHAP! II. COMPRESSIBILITY ELASTICITY. 21 
 
 the water had not escaped upon the change of figure of the 
 globe, the compressibility of the liquid would have been estab- 
 lished. The escape of the water does not, however, prove 
 its incompregsibility. To accomplish this, it would be neces- 
 sary first to measure accurately the volume of water which 
 transuded by compression, and next to measure the diminu- 
 tion of volume which the vessel suffered by its change of 
 figure. If this diminution were greater than the volume of 
 water which escaped, it would follow that the water remain- 
 ing in the globe had been compressed, notwithstanding the 
 escape of the remainder. But this could never be accom- 
 plished with the delicacy and exactitude necessary in such an 
 experiment ; and, consequently, as far as the question of the 
 compressibility of water was concerned, nothing was proved. 
 It forms, however, a very striking illustration of the porosity 
 of so dense a substance as gold, and proves that its pores are 
 larger than the elementary particles of water, since they are 
 capable of passing through them. 
 
 (30.) It has since been proved, that water, and other 
 liquids, are compressible. In the year 1761, Canton com- 
 municated to the Royal Society the results of some experi- 
 ments which proved this fact. He provided a glass tube 
 with a bulb, such as that described in (28.), and filled the 
 bulb and a part of the tube with the liquid well purified 
 from air. He then placed this in an apparatus called a con- 
 denser, by which he was enabled to submit the surface of 
 the liquid in the tube to very intense pressure of condensed 
 air. lie found that the level of the liquid in the tube fell in 
 a very perceptible degree upon the application of the pres- 
 sure. The same experiment established the fact, that liquids 
 are clastic. ; for, upon removing the pressure, the liquid rose 
 to its original level, and therefore resumed its former dimen- 
 sions. 
 
 (37.) Elasticity does not always accompany compressibil- 
 ity. If lead or iron be submitted to the hammer, it may be 
 hardened and diminished- in its volume ; but it will not re- 
 sume its former volume after each stroke of the hammer. 
 
 (3.^.) There are some bodies which maintain the state 
 of density in which they are commonly found by the continual 
 agency of mechanical pressure ; and such bodies are endued 
 with a quality, in virtue of which they would enlarge their 
 dimensions without limit, if the pressure which confines them 
 were removed. Such bodies are called clastic fluids or gases 
 
22 THE ELEMENTS OF MECHANICS. CHAP. II. 
 
 and always exist in the form of common air, in whose me- 
 chanical properties they participate. They are hence often 
 called aeriform fluids, 
 
 Those who are provided with an air-pump can easily estab- 
 lish this property experimentally. Take a flaccid bladder, 
 such as that already described in (27.), and place it under 
 the glass receiver of an air-pump : by this instrument we 
 shall be able to remove the air which surrounds the bladder 
 under the receiver, so as to relieve the small quantity of air 
 which is enclosed in the bladder from the pressure of the 
 external air : when this is accomplished, the bladder will be 
 observed to swell, as if it were inflated, and will be perfectly 
 distended. The air contained in it, therefore, has a tendency 
 to dilate, which takes effect when it ceases to be resisted by 
 the pressure of surrounding air. 
 
 (39.) It has been stated that the increase or diminution 
 of temperature is accompanied by an increase or diminution 
 of volume. Related to this, there is another phenomenon 
 too remarkable to pass unnoticed, although this is not the 
 proper place to dwell upon it: it is the con verse of the former; 
 viz. that an increase or diminution of bulk is accompanied 
 by a diminution or increase of temperature. As the applica- 
 tion of heat from some foreign source produces an increase 
 of dimensions, so if the dimensions be increased from any 
 other cause, a corresponding portion of the hea^ which the 
 body had before the enlargement, will be absorbed in the 
 process, and the temperature will be thereby diminished. 
 In the same way, since the abstraction of heat causes a dim- 
 inution of volume, so if that diminution be caused by any 
 other means, the body will ff-for. out, the heat which in the 
 other case was abstracted, and will rise in its temperature. 
 
 Numerous and well-known facts illustrate these observa- 
 tions. A smith, by hammering a piece of bar iron, and there- 
 by compressing it, will render it re.d hot. When air is vio- 
 lently compressed, it becomes so hot as to ignite cotton and 
 other substances. An ingenious instrument for producing 
 a light for domestic uses has been constructed, consisting of a 
 small cylinder, in which- a solid piston moves air-tight : a little 
 tinder, or dry sponge, is attached to the bottom of the piston, 
 which is then violently forced into the cylinder : the air be- 
 tween the bottom of the cylinder and the piston becomes 
 intensely compressed, and evolves so much heat as to light 
 the tinder. 
 
CHAP. III. ' INERTIA. 23 
 
 In all the cases where friction or percussion produces heat 
 or fire, it is because they are means of compression. The 
 effects of flints, of pieces of wood rubbed together, the 
 warmth produced by friction on the flesh, are all to be 
 attributed to the same cause. 
 
 CHAPTER III. 
 
 INERTIA. 
 
 (40.) THE quality of matter which is of all others the most 
 important in mechanical investigations, is that which has been 
 called Inertia. 
 
 Matter is incapable of spontaneous change. This is one 
 of the earliest and most universal results of human observa- 
 tion ; it is equivalent to stating that mere matter is deprived 
 of life ; for spontaneous action is the only test of the pres- 
 ence of the living principle. If we see a mass of matter 
 undergo any change, we never seek for the cause of that 
 change in the body itself; we look for some external cause 
 producing it. This inability for voluntary change of state or 
 qualities is a more general principle than inertia. At any 
 given moment of time, a body must be in one or other of two 
 states, rest or motion. Inertia, or inactivity, signifies the 
 total absence of power to change this state. A body endued 
 with inertia cannot of itself, and independent of all external 
 influence, commence to move from a state of rest ; neither 
 can it, when moving, arrest its progress, and become quies- 
 cent. 
 
 (41.) The same property by which a body is unable by 
 any power of its own to pass from a state of rest to one of 
 motion, or vice versa , also renders it incapable of increasing 
 or diminishing any motion which it may have received from 
 an external cause. If a body be moving in a certain direc 
 tion at the rate of ten miles per hour, it cannot, by any ener- 
 gy of its own, change its rate of motion to eleven or nine 
 miles an hour. This is a direct consequence of that mani- 
 festation of inertia which has just been explained. For the 
 same power which would cause a body moving at ten miles an 
 hour to increase its rate to eleven miles, would also cause the 
 same body at rest to commence moving at the rate of one 
 
24 THE ELEMENTS OF MECHANICS. CHAP. III. 
 
 mile an hour ; and the same power which would cause a 
 body moving at the rate of ten miles an hour to wove at the 
 rate of nine miles in the hour, would cause the :-ame body 
 moving at the rate of one mile an hour to become quiescent. 
 It therefore appears, that to increase or diminish the motion 
 of a body is an effect of the same kind as to change the state 
 of rest into that of motion, or vice versa. 
 
 (42.) The effects and phenomena which hourly fill under 
 our observation afford unnumbered examples of the inabil- 
 ity of lifeless matter to put itself into motion, or to increase 
 any motion which may have been communicated to it. But 
 it does not happen that we have the same direct and frequent 
 evidence of its inability to destroy or diminish any motion 
 which it may have received. And hence it arises, that, while 
 no one will deny to matter the former effect of inertia, few 
 will at firs; acknowledge the latter. Indeed, even so late 
 as the time of KEPLEU, philosophers themselves held it as a 
 maxim, that " matter is more inclined to rest than to motion ;" 
 we ought not, therefore, to be surprised if, in the present day, 
 those who have not been conversant with physical science 
 are slow to believe that a body once put in motion would 
 continue for ever to move with the same velocity, if it were 
 not stopped by some external cause. 
 
 Reason, assisted by observation, will, however, soon dispel 
 this illusion. Experience shows us in various ways, that the 
 same causes which destroy motion in one direction are capable 
 of producing as much motion in the opposite direction. Thus, 
 if a wheel, spinning on its axis with a certain velocity, be 
 stopped by a hand seizing one of the spokes, the effort which 
 accomplishes this is exactly the same as, had the wheel been 
 previously at rest, would have put it in motion in the opposite 
 direction with the same velocity. If a carriage drawn by 
 horses be in motion, the saint' exertion of power in the horses 
 is necessary to stop it, as would be necessary to back it, if it 
 were at rest. Now, if this be admitted as a general principle, 
 it must be evident that a body which can destroy or diminish 
 its own motion must also be capable of putting itself into 
 motion from a state of rest, or of increasing any motion 
 which it has received. But this latter is contrary to all 
 experience, and therefore we are compelled to admit that 
 a body cannot diminish or destroy any motion which it has 
 received. 
 
 Let us inquire why we are more disposed to admit the 
 
CHAP. III. INERTIA. 25 
 
 inability of matter to produce than to destroy motion in itself. 
 We see most of those motions which take place around us on 
 the surface of the earth subject to gradual decay, and if not 
 renewed from time to time, they at length cease. A stone 
 rolled along the ground, a wheel revolving on its axis, the 
 heaving of the deep after a storm, and all other motions pro- 
 duced in bodies by external causes, decay, when the exciting 
 cause is suspended ; and if that cause do not renew its ac- 
 tion, they ultimately cease. 
 
 But is there no exciting cause, on the other hand, which 
 thus gradually deprives those bodies of their motion ? and 
 if that cause were removed, or its intensity diminished, 
 would not the motion continue, or be more slowly retarded ? 
 When a stone is rolled along the ground, the inequalities 
 of its shape, as well as those of the ground, are impediments 
 which retard and soon destroy its motion. Render the stone 
 round, and the ground level, and the motion will be consider- 
 ably prolonged. But still small asperities will remain on the 
 stone, and on the surface over which it rolls : substitute for it 
 a ball of highly polished steel, moving on a highly polished 
 steel plane, truly level, and the motion will continue without 
 sensible diminution for a very long period ; but even here, 
 and in every instance of motions produced by art, minute 
 asperities must exist on the surfaces which move in contact 
 with each other, which must resist, gradually diminish, and 
 ultimately destroy the motion. 
 
 Independently of the obstructions to the continuation of 
 motion arising from friction, there is another impediment to 
 which all motions on the surface of the earth are liable 
 the resistance of the air. How much this may affect the 
 continuation of motion, appears by many familiar effects. On 
 a calm day, carry an open umbrella with its concave side 
 presented in the direction in which you are moving, and 
 a powerful resistance will be opposed to your progress, which 
 will increase with every increase of the speed with which you 
 move. 
 
 We are not, however, without direct experience to prove, 
 that motions when unresisted will for ever continue. In 
 the heavens we find an apparatus, whicli furnishes a sublime 
 verification of this principle. There, removed from all casual 
 obstructions and resistances, the vast bodies of the universe 
 roll on in their appointed paths with unerring regularity, 
 preserving without diminution all ftiat motion which they 
 3 
 
26 THE ELEMENTS OF MECHANICS. CHAP. Ill 
 
 received at their creation from the hand which launched 
 them into space. This alone, unsupported by other reasons, 
 would be sufficient to establish the quality of inertia ; but 
 viewed in connection with the other circumstances previously 
 mentioned, no doubt can remain that this is an universal law 
 of nature. 
 
 (43.) Organized bodies endued with the living principle, 
 seem to be the only exceptions to this law. But even in these 
 their members and all their component parts, separately con- 
 sidered, are inert, and are subject to the same laws as all 
 other forms of matter. The quality of animation, from which 
 they derive the power of spontaneous action or voluntary 
 motion, does not belong to the parts, but to the whole, and 
 not to the whole by any obvious or necessary connection, 
 because it is absent in sleep, and totally removed by death, 
 even while the organization of every part remains, to all ap- 
 pearance, without derangement. Seeing, then, the whole 
 visible material universe partaking in the common quality 
 of inertia, unable to trace the conditions of life to any ma- 
 terial phenomena, it is impossible not to conclude that the 
 will of animated beings is the result of an immaterial prin- 
 ciple, which, during the period of life, governs their organ- 
 ized bodies. In what this principle consists, what is its seat, 
 or by what modes of action it moves the body, we are wholly 
 unable to decide. But the same principle, analogy, which 
 guides our investigations in every other part of physical sci- 
 ence, ought to govern us in this ; and by that principle, the 
 spontaneous motion found in animated beings, but which in 
 no instance is manifested by mere matter, must be attrib- 
 uted not to the matter which composes the bodily forms of 
 these beings, but to something of altogether a different na- 
 ture. 
 
 Independently of this, which may be considered as the 
 reasoning proper to physical science, philosophers have given 
 another reason for assigning animation to an immaterial 
 principle. The will, from the very nature of its acts, must 
 belong to a simple, uncompounded, and indivisible being, 
 and consequently can never be an attribute of a thing which 
 in its essence is the very reverse of this. 
 
 (44.) It has been proved, that an inability to change the 
 quantity of motion is a consequence of inertia. The inability 
 to change the direction of motion is another consequence of 
 this quality. The same cause which increases or diminishes 
 
CHAP. III. SPONTANEOUS MOTION. 27 
 
 motion, would also give motion to a body at rest ; and there- 
 fore we inferred that the same inability which prevents a 
 body from moving itself, will also prevent it from increasing 
 or diminishing any motion which it has received. In the 
 same manner we can show, that any cause which changes 
 the direction of motion would also give motion to a body 
 at rest ; and therefore if a body change the direction of its 
 own motion, the same body might move itself from a state 
 of rest ; and therefore the power of changing the direction 
 of any motion which it may have received is inconsistent 
 with the quality of inertia. 
 
 (45.) If a body, moving from A, Jig. 3. to B, receive at 
 B a blow in the direction C B E, it will immediately change 
 its direction to that of another line B D. The cause which 
 produces this change of direction would have put the body in 
 motion in the direction B E, had it been quiescent at B when 
 it sustained the blow. 
 
 (46.) Again, suppose G H to be a hard plane surface; 
 and let the body be supposed to be perfectly inelastic. When 
 it strikes the surface at B, it will commence to move along 
 it in the direction B H. This change of direction is pro- 
 duced by the resistance of the surface. If the body, instead 
 of meeting the surface in the direction A B, had moved in 
 the direction E B, perpendicular to it, all motion would have 
 been destroyed, and the body reduced to a state of rest. 
 
 (47.) By the former example it appears, that the deflecting 
 cause would have put a quiescent body in motion, and by the 
 latter it would have reduced a moving body to a state of rest. 
 Hence the phenomenon of a change of direction is to be 
 referred to the same class as the change from rest to motion, 
 or from motion to rest. The quality of inertia is, therefore, 
 inconsistent with any change in the direction of motion which 
 does not arise from an external cause. 
 
 (48.) From all that has been here stated, we may infer 
 generally, that an inanimate parcel of matter is incapable 
 of changing its state of rest or motion ; that, in whatever state 
 it be, in that state it must for ever persevere, unless disturbed 
 by some external cause ; that if it be in motion, that motion 
 must always be uniform^ or must proceed at the same rate, 
 the equal spaces being moved over in the same time ; any 
 increase of its rate must betray ome impelling cause, any 
 diminution must proceed from an impeding cause, and nei- 
 ther of these causes can exist in the body itself; that such 
 
28 THE ELEMENTS OF MECHANICS. CHAP. III. 
 
 motion must not only be constantly of the same uniform rate, 
 but also must be always in the same direction, any deflec- 
 tion from its course necessarily arising from some external 
 influence. 
 
 The language sometimes used to explain the property of 
 inertia in popular works, is eminently calculated to mislead 
 the student. The terms resistance and stubbornness to move 
 are faulty in this respect. Inertia implies absolute passive- 
 ness, a perfect indifference to re&t or motion. It implies 
 as strongly the absence of all resistance to the reception of 
 motion, as it does the absence of all power to move itself. 
 The term vis inertia, or force of inaitivity, so frequently 
 used even by authors pretending to scientific accuracy, is 
 still more reprehensible. It is a contradiction in terms ; the 
 term inactivity implying the absence of all force. 
 
 (49.) Before we close this chapter, it may be advantageous 
 to point out gome practical and familiar examples of the 
 general law of inertia. The student must, however, recollect, 
 that the great object of science is generalization, and that 
 his mind is to be elevated to the contemplation of the laws 
 of nature, and to receive a habit the very reverse of that 
 which disposes us to enjoy the descent from generals to par- 
 ticulars. Instances, taken from the occurrences of ordinary 
 life, may, however, be useful in verifying the general law, 
 and in impressing it upon the memory ; and, for this reason, 
 we shall occasionally, in the present treatise, refer to such 
 examples ; always, however, keeping them in subservience 
 to the general principles of which they are manifestations, 
 and on which the attention of the student should be fixed. 
 
 (50.) If a carriage, a horse, or a boat, moving with speed, 
 be suddenly retarded or stopped, by any cause which does 
 not at the same time affect passengers, riders, or any loose 
 bodies which are carried, they will be precipitated in the 
 direction of the motion ; because, by reason of their inertia, 
 they persevere in the motion which they shared in common 
 with that which transported them, and are not deprived of 
 that motion by the same cause. 
 
 (51.) If a passenger leap from a carriage in rapid motion, 
 he will fall in the direction in which the carriage is moving 
 at the moment his feet meet the ground ; because his body, 
 on quitting the vehicle, retains, by its inertia, the motion 
 which it had in common with it. When he reaches ti.e 
 
CHAP. IV. ACTION AND REACTION. 29 
 
 ground, this motion is destroyed by the resistance of the 
 ground to the feet, but is retained in the upper and heavier 
 part of the body ; so that the same effect is produced as if 
 the feet had been tripped. 
 
 (52.) When a carriage is once put in motion with a deter- 
 minate speed on a level road, the only force necessary to 
 sustain the motion is that which is sufficient to overcome the 
 friction of the road ; but at starting a greater expenditure of 
 force is necessary, inasmuch as not only the friction is to be 
 overcome, but the force with which the vehicle is intended to 
 move must be communicated to it. Hence we see that 
 horses make a much greater exertion at starting than subse- 
 quently, when the carriage is in motion ; and we may also 
 infer the inexpediency of attempting to start at full speed, 
 especially with heavy carriages. 
 
 (53.) Coursing owes all its interest to the instinctive con- 
 sciousness of the nature of inertia which seems to govern 
 the measures of the hare. The greyhound is a comparatively 
 heavy body moving at the same or greater speed in pursuit 
 The hare doublfs, that is, suddenly changes the direction of 
 her course, and turns back at an oblique angle with the di- 
 rection in which she had been running. The greyhound, 
 unable to resist the tendency of itjs body v> persevere in the 
 rapid motion it had acquired, is urged forward many yards 
 before it is able to check its speed and return to the pursuit. 
 Meanwhile the hare is gaining ground in the other direction, 
 so that the animals are at a ^very considerable distance asun- 
 der when the pursuit is recommenced. In this way, a hare, 
 .hough much less fleet than a greyhound, will often escape it. 
 
 In racing, the horses shoot far beyond the winning-post 
 Before their course can be arrested 
 
 CHAPTER IV. 
 
 ACTION AND REACTION 
 
 (54.) THE effects of inertia or inactivity, considered in 
 the last chapter, are such as may be manifested by a single 
 insulated body, without reference to, or connection with, any 
 other body whatever. They might all be recognised if there 
 were but one body existing in the universe. There are, 
 3* 
 
30 THE ELEMENTS OF MECHANICS. CHAP. IV. 
 
 however, other important results of this law, to the develope- 
 ment of which two bodies at least are necessary. 
 
 (55.) If a mass A, Ji.fr. 4., moving towards C, impinge 
 upon an equal mass, which is quiescent at B, the two masses 
 will move together towards C after the impact, But it will 
 be observed, that their speed after the impact will be only 
 half that of A before it. Thus, after the impact, A loses 
 half its velocity ; and B, which was before quiescent, re- 
 ceives exactly this amount of motion. It appears, there- 
 fore, in this case, that B receives exactly as much motion as 
 A loses ; so that the real quantity of motion from B to C is 
 the same as the quantity of motion from A to B. 
 
 Now, suppose that B consisted of two masses, each equal 
 to A, it would be found that in this case the velocity of the 
 triple mass, after impact, would be one third of the velocity 
 from A to B. Thus, after impact, A loses two thirds of its 
 velocity, and, B consisting of two masses each equal to A, 
 each of these two receives one third of A's motion ; so that 
 the whole motion received by B is two thirds of the motion 
 of A before impact. By the impact, therefore, exactly as 
 much motion is received by B as is lost by A. 
 
 A similar result will be obtained, whatever proportion may 
 subsist between the masses A and B. Suppose B to be ten 
 times A ; then the whole motion of A must, after the impact, 
 be distributed among the parts of the united masses of A 
 and B : but these united masses are, in this case, eleven 
 times the mass of A. Now, as they all move with a common 
 inotjon, it follows that A's former motion must be equally 
 distributed among them ; so that each part shall have a.n 
 eleventh part of it. Therefore the velocity, after impact, will 
 be the eleventh part of the velocity of A before it. Thus A 
 loses, by the impact, ten eleventh parts of its motion, which 
 are precisely what B receives. 
 
 Again, if the masses of A and B be 5 and 7, then the 
 united mass, after impact, will be 12. The motion of A, 
 before impact, will be equally distributed between these twelve 
 parts, so that each part will have a twelfth of it ; but five of 
 these parts belong to the mass A, and seven to B ; hence B 
 will receive seven twelfths, while A retains five twelfths. 
 
 (56.) In general, therefore, when a mass A in motion 
 impinges on a mass B at rest, to find the motion of the united 
 mass after impact, " divide the whole motion of A into as 
 many equal parts as there are equal component masses in A 
 
CHAP. IV. ACTION AND REACTION. 31 
 
 and B together, and then B will receive, by the impact, as 
 many parts of this motion as it has equal component masses." 
 
 This is an immediate consequence of the property of inertia, 
 explained in the last chapter. If we were to suppose, that, 
 by their mutual impact, A were to give to B either more or 
 less motion than that which it (A) loses, it would necessarily 
 follow, that either A or B must have a power of producing or 
 of resisting motion, which would be inconsistent with the 
 quality of inertia already defined. For if A give to B more 
 motion than it loses, all the overplus or excess must be excited 
 in B by the action of A ; and, therefore, A is not inactive, 
 but is capable of exciting motion which it does not possess. 
 On the other hand, B cannot receive from A less motion than 
 A loses, because then B must be admitted to have the power 
 by its resistance of destroying all the deficiency ; a power 
 essentially active, and inconsistent with the quality of inertia. 
 
 (57.) If we contemplate the effects of impact, which we 
 have now described, as facts ascertained by experiment 
 (which they may be), we may take them as further verifica- 
 tion of the universality of the quality of inertia. But, on 
 the other hand, we may view them as phenomena which may 
 certainly be predicted from the -previous knowledge of that 
 quality ; and this is one of .many instances of the advantage 
 which science possesses over knowledge merely practical. 
 Having obtained by ^observation or experience a certain num- 
 ber of simple facts, and thence deduced the general qualities 
 of bodies, we .are enabled, by demonstrative reasoning, to 
 discover other facts which have never fallen under our obser- 
 vation, or, if so, may have never excited attention. In this 
 way, philosophers have discovered certain small motions and 
 slight changes which have taken place among the heavenly 
 bodies, and have directed the attention of astronomical ob- 
 servers to them, instructing them with the greatest precision 
 as to the exact moment of time, and the point of the firma- 
 ment to which they should direct the telescope, in order to 
 witness the predicted event. 
 
 (58.) Since, by the quality of inertia, a body can neither 
 generate nor destroy motion, it follows that when two bodies 
 act upon each other in any way whatever, the total quantity 
 of motion in a given direction, after the action takes place, 
 must be the same as before it, for otherwise some motion 
 would be produced by the action of the bodies, which would 
 contradict the principle that they are inert. The word " ac- 
 
 . 
 
32 THE ELEMENTS OF MECHANICS. CHAP. IV. 
 
 tion" is here applied, perhaps improperly, but according to the 
 usuge of mechanical writers, to express a certain phenomenon 
 or effect. It is, therefore, not to be understood as imply- 
 ing any active principle in the bodies to which it is attributed. 
 
 (59.) In the cases of collision of which we have spoken, 
 one of the masses B was supposed to be quiescent before the 
 impact. We shall now suppose it to be moving in the same 
 direction as A, that is, towards C, biit with a less velocity, so 
 that A shall overtake it, and impinge upon it. After the 
 impact, the two masses will move towards C wish a common 
 velocity, the amount of which we now propose to determine. 
 
 If the masses A and B be equal, then their motions or 
 velocities added together must be the motion of the united 
 mass after impact, since no motion can either be created or 
 destroyed by that event. But as A and B move with a com- 
 mon motion, this sum must be equally distributed between 
 them, and therefore each will move with a velocity equal to 
 half the sum of their velocities before the impact. Thus, if A 
 have the velocity 7, and B have 5, the velocity of the united 
 mass, after impact, is 6, being the half of 12, the sum of 7 
 and 5. 
 
 If A and B be not equal, suppose them divided into equal 
 component parts, and let A consist^of 8, and B of 6, equal 
 masses: let the velocity of A be 17, so that, the motion of 
 each of the 8 parts being 17, the motion of the whole will 
 be 136. In the same manner, let the velocity of B be 10, 
 the motion of each part being 10, the whole motion of the 6 
 parts will be 60. The sum of the two motions, therefore, 
 towards C is 196; and since none of this can be lost by the 
 impact, nor any motion added to it, this must also be the 
 whole motion of the united masses after impact. Being 
 equally distributed among the 14 component parts of which 
 these united masses consist, each part will have a fourteenth 
 of the whole motion. Hence, 196 being divided by 14, we 
 obtain the quotient 14, which is the velocity with which the 
 whole moves. * 
 
 (60.) In general, therefore, when two masses, moving in 
 the same direction, impinge one upon the other, and, after im- 
 pact, move together, their common velocity may be determin- 
 ed by the following rule : " Express the masses and velocities 
 by numbers in the usual way, and multiply the numbers ex- 
 pressing the masses by the numbers which express the veloci- 
 ties ; the two products thus obtained being added together, 
 
 
CHAP. IV. 
 
 ACTION AND REACTION. 
 
 33 
 
 and their sum divided by the sum of the numbers expressing 
 the masses, the quotient will be the number expressing the 
 required velocity." 
 
 (61.) From the preceding details, it appears that motion is 
 not adequately estimated by speed or velocity. For example, 
 a certain mass A, moving at a determinate rate, has a certain 
 quantity of motion. If another equal mass B be added to A, 
 and a similar velocity be given to it, as much more motion 
 will evidently be called into existence. In other words, the two 
 equal masses A and B united have twice as much motion as 
 the single mass A had when moving alone, and with the 
 same speed. The same reasoning will show that three, equal 
 masses will, with the same speed, have three times the motion 
 of anyone of them. In general, therefore, the velocity being 
 the same, the quantity of motion will always be increased 
 or diminished in the same proportion as the mass moved is 
 increased or diminished. 
 
 (02.) On the other hand, the quantity of motion does not 
 depend on the mass only, but also on the speed. If a certain 
 determinate mass move with a certain determinate speed, 
 another equal mass which moves with twice the speed, that 
 is, which moves over twice the space in the same time, will 
 have twice the quantity of motion. In this manner, the 
 mass being the same, the quantity of motion will increase or 
 diminish in the same proportion as the velocity. 
 
 (63.) The true estimate, then, of the quantity of motion 
 is found by multiplying together the numbers which express 
 the mass and the velocity. Thus, in the example which has 
 been last give*n of the impact of masses, the quantities of 
 motion before and after impact appear to be as follow : 
 
 Before Impact. ! 
 
 After Impact. 
 Mass of A 8 
 
 
 Velocity of A 17 
 
 Common velocity 14 
 
 
 Quantity of ) g 17 * Qr 13(J 
 motion ot A ^ 
 
 Quantity of ? fl ,, 
 motion of AS X1 
 
 or 112 
 
 Mass of B G 
 
 Mass of B 6 
 
 
 Velocity of B 10 
 
 Common velocity 14 
 
 
 Quantity of * 6 x 10 or fj0 
 motion of B $ 
 
 Quantity of ? fi 
 motion of B$ 
 
 14 = 84 
 
 * The sign X w hen placed between two numbers means that they are to be 
 multiplied together. 
 
34 THE ELEMENTS OF MECHANICS. CHAP. IV. 
 
 By this calculation it appears that in the impact A has lost 
 a quantity of motion expressed by 24, and that B has re- 
 ceived exactly .that amount. The effect, therefore, of the 
 impact is a transfer of motion from A to B ; but no new 
 motion is produced in the direction A C which did not exist 
 before. This is obviously consistent with the property of 
 inertia r and, indeed, an inevitable result of it. 
 
 (64.) This phenomenon is an example of a law deduced 
 from the property of inertia, and generally expressed thus 
 " Action and reaction are equal, arid in contrary directions." 
 The student must, however, be cautious not to receive these 
 terms in their ordinary acceptation. After the full explana- 
 tion of inertia given in the last chapter, it is, perhaps, scarcely 
 necessary here to repeat, that in the phenomena manifested 
 by the motion of two bodies, there can be neither " action" 
 nor " reaction," properly so called. The bodies are absolute- 
 ly incapable either of action or resistance. The ^ense in 
 which these words must be received, as used in the law, is 
 merely an expression of the transfer of a certain quantity 
 of motion from one body to another, which is called an action 
 in the body which loses the motion, and a reaction in the 
 body which receives it. The accession of motion to the latter 
 is said to proceed from the action of the former ; and the 
 loss of the same motion in the former is ascribed to the 
 reaction of the latter. The whole phraseology is, however, 
 most objectionable and unphilosophical, and is calculated to 
 create wrong notions. 
 
 (G5.) The bodies impinging were, in the last case, suppos- 
 ed to move in the same direction. We shall now consider 
 the case in which they move in opposite directions. 
 
 First, let the masses A and B be supposed to be equal, and 
 moving in opposite directions, with the same velocity. Let 
 C, Jig. 5., be the point at which they meet. The equal 
 motions in opposite directions will, in this case, destroy each 
 other, and both masses will be reduced to a state of rest. 
 Thus the mass A loses all its motion in the direction A C, 
 which it may be supposed to transfer to B at the moment 
 of impact. But B, having previously had an equal quantity 
 of motion in the direction B C, will now have two equal 
 motions impressed upon it, in directions immediately oppo- 
 site ; and, these motions neutralizing each other, the mass 
 becomes quiescent. In this case, therefore, as in all the 
 former examples, each body transfers to the other all the 
 
 
CHAP. IV. ACTION AND REACTION. 35 
 
 motion which it loses, consistently with the principle of " ac- 
 tion and reaction." 
 
 The masses A and B being still supposed equal, let them 
 move towards C with different velocities. Let A move with 
 the velocity 10, and B with the velocity 6. Of the 10 parts 
 of motion with which A is endued, 6 being transferred to B, 
 will destroy the equal velocity 6, which B has in the direction 
 B C. The bodies will then move together in the direction 
 C B, the four remaining parts of A's motion being equally 
 distributed between them. Each body will, therefore, have 
 two parts of A's original motion, and 2, therefore, will be their 
 common velocity after impact. In this case, A loses 8 of the 
 10 parts of its motion in the direction A C. On the other 
 hand, B loses the entire of its 6 parts of motion in the direc- 
 tion B C, and receives 2 parts in the direction A C. This is 
 equivalent to receiving 8 parts of A's motion in the direction 
 A C. Thus, according to the law of " action and reaction," 
 B receives exactly what A loses. . 
 
 Finally, suppose that both the masses and velocities of A 
 and B are unequal. Let the mass of A be 8, and its velocity 
 9 ; and let the mass of B be 6, and its velocity 5. The 
 quantity of motion of A will be 72, and that of B, in the oppo- 
 site direction, will be 30. Of the 72 parts of motion, which 
 A has in the direction A C, 30, being transferred to B, will 
 destroy all its 30 parts of motion in the direction B C, and 
 the two masses will move in the direction C B, with the 
 remaining 42 parts of motion, which will be equally distrib- 
 uted among their 14 component masses. Each component 
 part will, therefore, receive three parts of motion ; and ac- 
 cordingly 3 will be the common velocity of the united mass 
 after impact. 
 
 (66.) When two masses, moving in opposite directions, 
 impinge and move together, their common velocity after im- 
 pact may be found by the following rule : " Multiply the 
 numbers expressing the masses by those which express the 
 velocities respectively, and subtract the lesser product from 
 the greater ; divide the remainder by the sum of the num- 
 bers expressing the masses, and the quotient will be the com- 
 mon velocity ; the direction will be that of the mass which 
 has the greater quantity of motion." 
 
 It may be shown without difficulty, that the example 
 which we have just given obeys the law of "action and 
 reaction." 
 
 
THE ELEMENTS OF MECHANICS. CHAP. IV. 
 
 Before Impact. 
 
 Mass of A 8 
 
 Velocity of A ... . . 9 
 
 Quantity of motion ? ft v n m . 7 o 
 
 in direction A C 
 
 Mass of B . 6 
 
 Velocity of B 5 
 
 Quantity of motion 
 
 in direction B C 
 
 After Impact. 
 
 Mass of A 8 
 
 Common velocity ... 3 
 
 Quantity of motion ? Q ^ Q n o/i 
 
 hi direction A C 
 Mass of B ....... 6 
 
 Common velocity ... 3 
 
 Quantity of motion ? - .. Q _ no 
 .1: " *: A r f X o Or 18 
 
 hi direction A C 
 
 Hence it appears that the quantity of motion in the direction 
 A C, of which A has been deprived by the impact, is 48, the 
 difference between 72 and 24. On the other hand, B loses 
 by the impact the quantity 30 in the direction B C, which is 
 equivalent to receiving 30 in thG direction A C. But it also 
 acquires a quantity 18 in the direction A C, which, added 
 to the former 30, gives a total of 48 received by B in the 
 direction A C. Thus the same quantity of motion which A 
 loses in the direction A C, is received by B in the same 
 direction. The law of " action and reaction" is, therefore, 
 fulfilled. 
 
 (67.) The examples of the equality of action and reaction 
 in the collision of bodies may be exhibited experimentally by 
 a very simple apparatus. Let A, Jig. 6., and B be two balls 
 of soft clay, or any other substance which is inelastic, or 
 nearly so, and let these be suspended from C by equal strings, 
 so that they may be in contact ; and let a graduated arch, 
 of which the centre is C, be placed so that the balls may 
 oscillate over it. One of the bulls being moved from its place 
 of rest along the arch, and allowed to descend upon the 
 other through a certain number of degrees, will strike the 
 other with a velocity corresponding to that number of de- 
 grees, and both balls will then move together with a velo- 
 city which may be estimated by the number of degrees of 
 the arch through which they rise. 
 
 (68.) In all these cases in which we have explained the 
 law of " action and reaction," the transfer of motion from 
 one body to the other has been made by impact or collision. 
 This phenomenon has been selected only because it is the 
 most ordinary way in which bodies are seen to affect each 
 other. The law is, however, universal, and will be fulfilled 
 in whatever manner the bodies may effect each other. Thus 
 A may be connected with B by a flexible string, which, at 
 
CHAP. IV. ACTION AND REACTION. 37 
 
 the commencement of A's motion, is slack. Until the 
 string becomes stretched, that is, until A's distance from B 
 becomes equal to the length of the string, A will continue 
 to have all the motion first impressed upon it. But when the 
 string is stretched, a part of that motion is transferred to B, 
 which is then drawn after A ; and whatever motion B in 
 this way receives, A must lose. All that has been observed 
 of the effect of motion transferred by impact will be equally 
 applicable in this case. 
 
 Again, if B, jig. 4., be a magnet moving in the direction 
 B C with a certain quantity of motion, and, while it is so 
 moving, a mass of iron be placed at rest at A, the attraction 
 of the magnet will draw the iron after it towards C, and 
 will thus communicate to the iron a certain quantity of mo- 
 tion in the direction of C. All the motion thus communi- 
 cated to the iron A must be lost by the magnet B. 
 
 If the magnet and the iron were both placed quiescent 
 at B and A, the attraction of the magnet would cause the 
 iron to move from A towards B ; but the magnet, in this case, 
 not having any motion, cannot be literally said to transfer a 
 motion to the iron. At the moment, however, when the 
 iron begins to move from A towards B, the magnet will be 
 observed to begin also to move from B towards A ; and 
 if the velocities of the two bodies be expressed by numbers, 
 and respectively multiplied by the numbers expressing their 
 masses, the quantities of motion thus obtained will be found 
 to be exactly equal. We have already explained why a quan- 
 tity of motion received in the direction B A is equivalent 
 to the same quantity lost in the direction A B. Hence it 
 appears, that the magnet, in receiving as much motion in 
 the direction B A, as it gives in the direction A B, suffers 
 an effect which is equivalent to losing as much motion direct- 
 ed towards C as it has communicated to the iron in the 
 same direction. 
 
 In the same manner, if the body B had any property in 
 virtue of which it might repel A, it would itself be repelled 
 with the same quantity of motion. In a word, whatever be 
 the manner in which the bodies may affect each other, wheth- 
 er by collision, traction, attraction, or repulsion, or by what- 
 ever other name the phenomenon may be designated, still 
 it is an inevitable consequence, that any motion, in a given 
 direction, which one of the bodies may receive, must be 
 accompanied by a loss of motion in the same direction, and 
 
 4 . 
 
38 THE ELEMENTS OF MECHANICS. CHAP. ty*. 
 
 - *' ' f 
 
 to tne same amount, by the other body, or the acquisition 
 of as much motion in the contrary direction ; or, finally, by 
 a loss in the same direction, and an acquisition of motion in 
 the contrary direction, the combined amount of which is 
 equal to the motion received by the former. 
 
 (69.) From the principle, that the force of a body in mo- 
 tion depends on the mass and the velocity, it follows, that 
 any body, however small, may be made to move with the 
 same force as any other body, however great, by giving to the 
 smaller body a velocity which bears to that of the greater 
 the same proportion as the mass of the greater bears to the 
 mass of the smaller. Thus a feather, ten thousand of which 
 would have the same weight as a cannon-ball, would move 
 with the same force if it had ten thousand times the velocity ; 
 and, in such a case, these two bodies, encountering in oppo- 
 site directions, would mutually destroy each other's mo- 
 tion. 
 
 (70.) The consequences of the property of inertia, which 
 have been explained in the present and preceding chapters, 
 have been given by Newton, in his PRINCIPIA, and, after him, 
 in most English treatises on mechanics, under the form of 
 three propositions, which are called the " laws of motion." 
 They are as follow : 
 
 I. 
 
 " Every body must persevere in its state of rest, or of 
 uniform motion in a straight line, unless it be compelled 
 to change that state by forces impressed upon it." 
 
 It 
 
 " Every change of motion must be proportional to the 
 impressed force, and must be in the direction of that straight 
 line in which the force is impressed." 
 
 III. 
 
 " Action must always be equal, and contrary to reaction ; 
 or the actions of two bodies upon each other must be equal, 
 and directed towards contrary sides." 
 
 When inertia and force are defined, the first law becomes 
 an identical proposition. The second law cannot be render- 
 ed perfectly intelligible until the student has read the chapter 
 on the composition and resolution of forces, for, in fact, it is 
 intended as an expression of the whole body of results in 
 
 
CHAP. IV. FAMILIAR ILLUSTRATIONS. 39 
 
 that chapter. The third law has been explained in the 
 present chapter as far as it can be rendered intelligible in 
 the present stage of our progress. 
 
 We have noticed these formularies more from a respect 
 for the authorities by which they have been adopted, than 
 from any persuasion of their utility. Their full import can- 
 not be comprehended until nearly the whole of elementary 
 mechanics has been acquired, and then all such summaries 
 become useless. 
 
 (71.) The consequences deduced from the consideration 
 of the quality of inertia in this chapter, will account for many 
 effects which fall under our notice daily, and with which we 
 have become so familiar, that they have almost ceased to 
 excite curiosity. One of the facts of which we have most 
 frequent practical illustration is, that the quantity of motion, 
 or moving fore*, as it is sometimes called, is estimated by 
 the velocity of the motion, and the weight or mass of the 
 thing moved, conjointly. 
 
 If the same force impel two balls, one of one pound weight, 
 and the other of two pounds, it follows, since the balls can 
 neither give force to themselves nor resist that which is im- 
 pressed upon them, that they will move with the same force. 
 But the lighter ball will move with twice the speed of the 
 heavier. The impressed force which is manifested by giving 
 velocity to a double mass in the one, is engaged in giving a 
 double velocity to the other. 
 
 If a cannon-ball were forty times the weight of a musket- 
 ball, but the musket-ball moved with forty times the velocity 
 of the cannon-ball, both would strike any obstacle with the 
 same force, and would overcome the same resistance ; for 
 the one would acquire from its velocity as much force as the 
 other derives from its weight. 
 
 A very small velocity may be accompanied by enormous 
 force, if the mass which is moved with that velocity be propor- 
 tionally great. A large ship floating near the pier wall, may 
 approach it with so small a velocity as to be scarcely per- 
 ceptible, and yet the force will be so great as to crush a 
 small boat. 
 
 A grain of shot flung from the hand, and striking the 
 person, will occasion no pain, and, indeed, will scarcely be 
 nit, while a block of stone having the same velocity would 
 occasion death. 
 
40 
 
 THE ELEMENTS OF MECHANICS. CHAP. IV 
 
 If a body in motion strike a body at rest, the striking 
 body must sustain as great a shock from the collision as if it 
 had been at rest, and struck by the other body with the same 
 force. For the loss of force which it sustains in the one 
 direction, is an effect of the same kind as if, being at rest, 
 it had received as much force in the opposite direction. If a 
 man, walking rapidly, or running, encounters another stand- 
 ing still, he suffers as much from the collision as the man 
 against whom he strikes. 
 
 If a leaden bullet be discharged against a plank of hard 
 wood, it will be found that the round shape of the ball is 
 destroyed, and that it has itself suffered a force by the im- 
 pact, which is equivalent to the effect which it produces upon 
 the plank. 
 
 When two bodies moving in opposite directions meet, each 
 body sustains as great a shock as if, being at rest, it had been 
 struck by the other body with the united forces of the two. 
 Thus, if two equal balls, moving at the rate of ten feet in 
 a second, meet, each will be struck with the same force as 
 if, being at rest, the other had moved against it at the rate 
 of twenty feet in a second. In this case, one part of the 
 shock sustained arises from the loss of force in one direction, 
 and another from the reception of force in the opposite 
 direction. 
 
 For this reason, two persons walking in opposite directions 
 receive from their encounter a more violent shock than might 
 be expected. If they be of nearly equal weight, and one be 
 walking at the rate of three and the other four N miles an 
 hour, each sustains the same shock as if he had been at rest, 
 and struck by the other running at the rate of seven miles an 
 hour. 
 
 This principle accounts for the destructive effects arising 
 from ships running foul of each other at sea. If two ships 
 of 500 tons burden encounter each other, sailing at ten knot*? 
 an hour, each sustains the shock which, being at rest, it 
 would receive from a vessel of 1000 tons burden sailing ten 
 knots an hour. 
 
 It is a mistake to suppose, that when a large and small 
 body encounter, the small body suffers a greater shock than 
 the large one. The shock which they sustain must be the 
 same ; but the large body may be better able to bear it. 
 
 When the fist of a pugilist strikes the body of his an- 
 tagonist, it sustains as great a shock as it gives ; but the 
 
 
CHAP. V. COMPOSITION AND RESOLUTION OF FORCE. 41 
 
 part being more fitted to endure the blow, the injury and 
 pain are inflicted on his opponent. This is not the case, 
 however, when fist meets fist. Then the parts in collision 
 are equally sensitive and vulnerable, and the effect is aggra- 
 vated by both having approached each other with great force. 
 The effect of the blow is the same as if one fist, being held 
 at rest, were struck by the other with the combined force of 
 both. 
 
 CHAPTER V. 
 
 THE COMPOSITION AND RESOLUTION OF FORCE. 
 
 (72.) MOTION and pressure are terms too familiar to need 
 explanation. It may be observed, generally, that definitions 
 in the first rudiments of a science are seldom, if ever, com- 
 prehended. The force of words is learned by their applica- 
 tion ; and it is not until a definition becomes useless, that 
 we are taught the meaning of the terms in which it is ex- 
 pressed. Moreover, we are perhaps justified in saying, that, 
 in the mathematical sciences, the fundamental notions are 
 of so uncompounded a character, that definitions, when de- 
 veloped and enlarged upon, often draw us into metaphysical 
 subtleties and distinctions, which, whatever be their merit or 
 importance, would be here altogether misplaced. We shall, 
 therefore, at once take it for granted, that the words motion 
 and pressure express phenomena or effects which are the 
 subjects of constant experience and hourly observation ; and 
 if the scientific use of these words be more precise than 
 their general and popular application, that precision will 
 soon be learned by their frequent use in the present treatise. 
 
 (73.) FORCE is the name given in mechanics to whatever 
 produces motion or pressure. This word is also often used 
 to express the motion or pressure itself; and when the cause 
 of the motion or pressure is not known, this is the only cor- 
 rect use of the word. Thus, when a piece of iron moves 
 toward a magnet, it is usual to say that the cause of the motion 
 is "the attraction of the magnet;" but in effect we are igno- 
 rant of the muse of this phenomenon ; and the name attrac- 
 tion would be better applied to the effect, of which we have 
 exnerience. In like manner the attraction and repulsion of 
 4* 
 
4*2 THE ELEMENTS OF MECHANICS. CHAP. V 
 
 electrified bodies should be understood, not as names for un- 
 known causes, but as words expressing observed appearances 
 or effects. 
 
 When a certain phraseology has, however, gotten into gen- 
 eral use, it is neither easy nor convenient to supersede it. 
 We shall, therefore, be compelled, in speaking of motion and 
 pressure, to use the language of causation ; but must advise 
 the student that it is effects, and not causes, which will be 
 expressed. 
 
 (74.) If two forces act upon the same point of a body in 
 different directions, a single force may be assigned, which, 
 acting on that point, will produce the same result as the 
 united effects of the other two. 
 
 Let P,Jig- 7., be the point on which the two forces act, 
 and let their directions be P A and P B. From the point P, 
 upon the line P A, take a length P , consisting of as many 
 inches as there are ounces in the force P A : and, in like 
 manner, take P >, in the direction P B, consisting of as many 
 inches as there are ounces in the force P B. Through a 
 draw a line parallel to P B, and through b draw a line parallel 
 to P A, and suppose that these lines meet at c. Then draw 
 PC. A single force, acting in the direction P C, and con- 
 sisting of as many ounces as the line P c. consists of inches, 
 will produce upon the point P the same effect as the two 
 forces P A and P B produce acting together. 
 
 (75.) The figure P a c b is called, in GEOMETRY, a parallel- 
 ogram ; the lines P , P b, are called its sides, and the line P 
 c is called its diagonal. Thus the method of finding an 
 equivalent for two forces, which we have just explained, is 
 generally called " the parallelogram of forces," and is usually 
 expressed thus : " If two forces be represented in quantity 
 and direction by the sides of a parallelogram, an equivalent 
 force will be represented in quantity and direction by its 
 diagonal." 
 
 (70.) A single force, which is thus mechanically equivalent 
 to two or more other forces, is called their resultant, and 
 relatively to it they are called its components. In any me- 
 chanical investigation, when the result is used for the compo- 
 nents, which it always may be, the process is called " the 
 composition of force." It is, however, frequently expedient 
 to substitute for a single force two or more forces, to which 
 it is mechanically equivalent, or of which it is the resultant. 
 This process is called ' the resolution of force." 
 
CHAP. V. PARALLELOGRAM OF FORCES. 43 
 
 (77.) To verify experimentally the theorem of the parallel- 
 ogram of forces is not difficult. Let two small wheels, M N, 
 Jig. 8, with grooves in their edges to receive a thread, be 
 attached to an upright board, or to a wall. Let a thread be 
 passed over them, having weights, A and B, hooked upon 
 loops at its extremities. From any part P of the thread be- 
 tween the wheels let a weight. C be suspended : it will draw 
 the thread downwards, so as to form an angle M P N, and 
 the apparatus will settle itself at rest in some determinate po- 
 sition. In this state it is evident that, since the weight C, 
 acting in the direction P C, balances the weights A and B, 
 acting in the directions P M and P N, these two forces must 
 be mechanically equivalent to a force equal to the weight C, 
 and acting directly upwards from P. The weight C is there- 
 fore the quantity of the resultant of the forces P M and P N; 
 and the direction of the resultant is that of a line drawn 
 directly upwards from P. 
 
 To ascertain how far this is consistent with the theorem of 
 " the parallelogram of forces," let a line P O be drawn upon 
 the upright board to which the wheels are attached, from the 
 point P upward, in the direction of the thread C P. Also, 
 let lines be drawn upon the board immediately under the 
 threads P M and P N. From the point P, on the line P O, 
 take as many inches as there are ounces in the weight C. 
 Let the part of P O thus measured be P c, and from c draw 
 c a parallel to P N, and c 5 parallel to P M. If the sides 
 P and P b of the parallelogram, thus formed, be measured, 
 it will be found that P a will consist of as many inches as 
 here are ounces in the weight A', and P b of as many inches 
 s there are ounces in the weight B. 
 
 In this illustration, ounces and inches have been used as the 
 subdivisions of ibcigkt and length. It is scarcely necessary to 
 state, that any other measures of these quantities would serve 
 as well, only observing that the same denominations must 
 be preserved in all parts of the same investigation. 
 
 (78.) Among the philosophical apparatus of the University 
 of London, is a very simple and convenient instrument which 
 I have constructed for the experimental illustration of this im- 
 portant theorem. The wheels M N are attached to the tops 
 of two tall stands, the heights of which may be varied at 
 pleasure by an adjusting screw. A jointed parallelogram, 
 A B C D, fig. 9., is formed, whose sides are divided into 
 
44 THE ELEMENTS OF MECHANICS. CHAP. V 
 
 inches, and the joints at A and B are movable, so as to vary 
 the lengths of the sides at pleasure. The joint C is fixed at 
 the extremity of a ruler, also divided into inches, while the 
 opposite joint A is attached to a brass loop, which surrounds 
 the diagonal ruler loosely, so as to slide freely along it. An 
 adjusting screw is provided in this loop so as to clamp it in 
 any required position. 
 
 In making the experiment, the sides A B and A D, C B 
 and C D, are adjusted by the joints B and A to the same 
 number of inches respectively as there are ounces in the 
 weights A and B,^'. 8. Then the diagonal A C is adjusted 
 by the loop and screw at A, to as m;my inches as there are 
 ounces in the weight C. This done, the point A is placed 
 behind ,jig. 8., and the parallelogram is held upright, so 
 that the diagonal A C shall be in the direction of the vertical 
 thread P C. The sides A B and A D will then be found to 
 take the direction of the threads P M and P N. By chang- 
 ing the weights and the lengths of the diagonal and sides of 
 the parallelogram, the experiment may be easily varied at 
 pleasure. 
 
 (79.) In the examples of the composition of forces which 
 we have here given, the effects of the forces are the produc- 
 tion of pressures ; or, to speak more correctly, the theorem 
 which we have illustrated, is " the composition of pressures." 
 For the point P is supposed to be- at rest, and to be drawn or 
 pressed in the directions P M and P N. In the definition 
 which has been given, of the word force, it is declared to 
 include motions as well as pressures. In fact, if motion be 
 resisted, the effect is converted, into pressure. The same 
 cause, acting upon a body, will either produce motion or pres- 
 sure, according as the body is free or restrained. If the 
 body be free, motion ensues; if restrained, pressure, or both 
 these effects together. It is therefore consistent with analo- 
 gy to expect that the same theorems which regulate pressures, 
 will also be applicable to motions ; and we find accordingly 
 a most exact correspondence. ' 
 
 (80.) If a body have a motion in the direction A B, and 
 at the point P it receive another motion, such as w r ould carry 
 it in the direction P C,Jig. 10., were it previously quiescent 
 at P, it is required to determine the direction which the body 
 will take, and the speed with which it will move, under these 
 circumstances. 
 
CHAP. V. COMPOSITION OF FORCES. 45 
 
 Let the velocity with which the body is moving from A to 
 B be such, that it would move through a certain space, sup- 
 pose P N, in one second of time, and let the velocity of the 
 motion impressed upon it at P be such, that, if it had no 
 previous motion, it would move from P to M in one second. 
 From the point M draw a line parallel to P B, and from N 
 draw a line parallel to P C, and suppose these lines to meet 
 at some point, as O. Then draw the line P 0. In conse- 
 quence of the two motions, which are at the same time 
 impressed upon the body at P, it will move in the straight 
 line from P to 0. 
 
 Thus the two motions, which are expressed in quantity and 
 direction by the sides of a parallelogram, will, when given to 
 the same body, produce a single motion, expressed in quanti- 
 ty and direction by its diagonal ; a theorem which is to 
 motions exactly what the former was to pressures. 
 
 There are various methods of illustrating experimentally 
 the composition of motion. An ivory ball, being placed upon 
 a perfectly level, square table, at one of the corners, and 
 receiving two equal impulses, in the directions of the sides 
 of the table, will .move along the diagonal. Apparatus for 
 this experiment differ from each other only in the way of 
 communicating the impulses to the ball. 
 
 (81.) As two motions simultaneously communicated to a 
 body are equivalent to a single motion in an intermediate 
 direction, so also a single motion may be mechanically re- 
 placed, by two motions in directions expressed by the sides of 
 any parallelogram, whose diagonal represents the single mo- 
 tion. This process is " the resolution of motion," and gives 
 considerable clearness and facility/ to many mechanical inves- 
 tigations. 
 
 (82.) It is frequently necessary to express the portion of a 
 given force, which acts in some given direction different from 
 the immediate direction of the force itself. Thus, if a force 
 act from A., Jig. 11., in the direction A C, we may require to 
 estimate what part of thnt force acts in the direction A B. 
 If the force be a pressure, take as many inches A P from A, 
 on the line A C, as there are ounces in the force, and from P 
 draw P M perpendicular to A B ; then the part, of the force 
 which acts along A B will be as many ounces as there are 
 inches in A M. The force A B is mechanically equivalent to 
 two forces, expressed by the sides A M.and A N of the par- 
 allelogram : but A N, boing perpendicular to A B, can have 
 
46 THE ELEMENTS OF MECHANICS. CHAP. V. 
 
 no effect on a body at A, in the direction of A B, and there- 
 fore the effective part of the force A P in the direction A B 
 is expressed by A M. 
 
 (83.) Any number of forces acting on the same point of a 
 body may be replaced by a single force, which is mechanical- 
 ly equivalent to them, and which is, therefore, their resultant. 
 This composition may be effected by the successive applica- 
 tion of the parallelogram of forces. Let the several forces 
 be called A, B, C, D, E, &c. Draw the parallelogram whose 
 sides express the forces A and B, and let its diagonal be A'. 
 The force expressed by A' will be equivalent to A and B. 
 Then draw the parallelogram whose sides express the forces 
 A' and C, and let its diagonal be B 7 . This diagonal will 
 express a force mechanically equivalent to A' and C. But 
 A' is mechanically equivalent to A and B, and therefore B 7 is 
 mechanically equivalent to A, B, and C. Next construct a 
 parallelogram, whose sides express the forces B' and D, and 
 let its diagonal be C'. The force expressed by C' will be 
 mechanically equivalent to the forces B' and D; but the 
 force B' is equivalent to A, B, C, and therefore C' is equiva- 
 lent to A, B, C, and D. By continuing this process, it is 
 evident, that a single force may be found, which will be 
 equivalent to, and may be always substituted for, any number 
 of forces which act upon the same point. 
 
 If the forces which act upon the point neutralize each 
 other, so that no motion can ensue, they are said to be in 
 equilibrium. 
 
 (84.) Examples of the composition of motion and pressure 
 are continually presenting themselves. They occur in almost 
 every instance of motion or force which falls under our ob- 
 servation. The difficulty is, to find an example which, strict- 
 "y speaking, is a simple motion. 
 
 When a boat is rowed across a river, in which there is a 
 current, it will not move in the direction in which it is im- 
 pelled by the oars. Neither will it take the direction of the 
 stream, but will proceed exactly in that intermediate direction 
 which is determined by the composition of force. 
 
 Let A, Jig. 12., be the place of the boat at starting; and 
 suppose that the oars are so worked as to impel the boat to- 
 wards B with a force which would carry it to B in one hour, 
 if there were no current in the river. But, on the other hand, 
 suppose the rapidity of the current is such, that, without any 
 

 CHAP. V. FAMILIAR EXAMPLES. 47 
 
 exertion of the rowers, the boat would float down the stream 
 in one hour to C. From C draw C D parallel to A B, and 
 draw the straight line A D diagonally. The combined effect 
 of the oars and the current will be, that the boat will be car- 
 ried along A D, and will arrive at the opposite bank in one 
 hour, at the point D. 
 
 If the object be, therefore, to reach the point B, starting 
 from A, the rowers must calculate, as nearly as possible, the 
 velocity of the current. They must imagine a certain point 
 E at such a distance above B that the boat would be floated 
 by the stream from E to B in the time taken in crossing the 
 river in the direction A E, if there were no current. If they 
 row towards the point E, the boat will arrive at the point B, 
 moving in the line A B. 
 
 In this case, the boat is impelled by two forces, that of the 
 oars in the direction A E, and that of the current in the di- 
 rection A C. The result will be, according to the parallelo- 
 gram of forces, a motion in the diagonal A B. 
 
 The wind and tide acting upon a vessel is a case of a 
 similar kind. Suppose that the wind is made to impel the 
 vessel in the direction of the keel ; while the tide may be 
 acting in any direction oblique to that of the keel. The 
 course of the vessel is determined exactly in the same man- 
 ner as that of the boat in the last example. 
 
 The action of the oars themselves, in impelling the boat, is 
 an example of the composition of force. Let A, jig. 13., be 
 the head, and B the stern of the boat. The boatman pre- 
 sents his face towards B, and places the oars so that their 
 blades press against the water in the directions C E, D F. 
 The resistance of the water produces forces on the side of 
 the boat, in the directions G L and H L, which, by the com- 
 position of force, are equivalent to the diagonal force K L, 
 in the direction of the keel. 
 
 Similar observations will apply to almost every body, im- 
 pelled by instruments projecting from its sides, and acting 
 against a fluid. The motions of fishes, the act of swimming, 
 the flight of birds, are all instances of the same kind. 
 
 (85.) The action of wind upon the sails of a vessel, and 
 the force thereby transmitted to the keel, modified by the 
 rudder, is a problem which is solved by the principles of the 
 composition and resolution of force ; but it is of too compli- 
 cated and difficult a nature to be introduced with all its 
 necessary conditions and limitations in this place. The 
 
48 THE ELEMENTS OF MECHANICS. CHAP. V. 
 
 question may, however, be simplified, if we consider the 
 canvass of the sails to be stretched so completely as to form 
 a plane surface. Let A B,^. 14., be the position of the sail, 
 and let the wind blow in the direction C D. If the line C D 
 be taken to express the force of the wind, let D E C F be a 
 parallelogram, of which it is the diagonal. The force C J) 
 is equivalent to two forces, one in the direction F D of the 
 plane of the canvass, and the other E D perpendicular to the 
 sail. The effect, therefore, is the same as if there were two 
 winds, one blowing in the direction of F D or B A, that is, 
 against the edge of the sail, and the other, E D, blowing full 
 against its face. It is evident that the former will produce 
 no effect whatever upon the sail, and that the latter will urge 
 the vessel in the direction D G. 
 
 Let us now consider this force D G as acting in the diago- 
 nal of the parallelogram D H G I. It will be equivalent to 
 two forces, D H and D I, acting along the sides. One of 
 these forces, D H, is in the direction of the keel, and the 
 other, D I, at right angles to the length of the vessel, so as 
 to urge it sideways. The form of the vessel is evidently 
 such as to offer a great resistance to the latter force, and very 
 little to the former. It consequently proceeds with consider- 
 able velocity in the direction D H of its keel, and makes 
 way very slowly in the sideward direction D I. The latter 
 effect is called lee-way. 
 
 From this explanation it will be easily understood, how a 
 wind which is nearly opposed to the course of a vessel may, 
 nevertheless, be made to impel it by the effect of sails. The 
 angle B D V, formed by the sail and the direction of the 
 keel, may be very oblique, as may also be the angle C D B 
 formed by the direction of the wind and that of the sail. 
 Therefore the angle C D V, made up of these two, and which 
 is that formed by the direction of the wind and that of the 
 keel, may be very oblique. In Jig- 15. the wind is nearly 
 contrary to the direction of the keel, and yet there is an 
 impelling force expressed by the line D H, the line C D ex- 
 pressing, as before, the whole force of the wind. 
 
 In this example there are two successive decompositions 
 of force. First, the original force of the wind C I) is re- 
 solved into two, E D and F D ; and next the element E D, 
 or its equal D G, is resolved into D I and D H ; so that the 
 original force is resolved into three, viz. F D, D I, D H, 
 which, taken together, are mechanically equivalent to it. 
 
CHAP. V. FAMILIAR EXAMPLES. 49 
 
 The part F D is entirely ineffectual ; it glides off on the sur- 
 face of the canvass without producing any effect upon the 
 vessel. The part D I produces Ice-way, and the part D II 
 impels. 
 
 (86.) If the wind, however, be directly contrary to the 
 course which it is required that the vessel should take, there 
 is no position which can be given to the sails which will im- 
 pel the vessel. In this case, the required course itself is 
 resolved into two, in which the vessel sails alternately, a 
 process which is called tacking. Thus, suppose the vessel is 
 required to move from A to E,^>\ 16., the wind setting from 
 E to A. The motion A B being resolved into two, by being 
 assumed as the diagonal of a parallelogram, the sides A a 
 a B of the parallelogram are successively sailed over, and 
 the vessel by this means arrives at B, instead of moving along 
 the diagonal A B. In the same manner she moves along B b, 
 b C, C c, c D, D d, d E, and arrives at E. She thus sails 
 continually at a sufficient angle with the wind to obtain an 
 impelling force, yet at a sufficiently small angle to make way 
 in her proposed course. 
 
 The consideration of the effect of the rudder, which we 
 have omitted in the preceding illustration, affords another 
 instance of the resolution of force. We shall not, however, 
 pursue this example further. 
 
 (87.) A body falling from the top of the mast when the 
 vessel is in full sail, is an example of the composition of mo- 
 tion. It might be expected, that, during the descent of the 
 body, the vessel, having sailed forward, would leave it behind, 
 and that, therefore, it would fall in the water behind the 
 stern, or at least on the deck, considerably behind the mast. 
 On the other hand, it is found to fall at the foot of the mast, 
 exactly as it would if the vessel were not in motion. To 
 account for this, let A B, jig. 17., be the position of the 
 mast when the body at the top is disengaged. The mast is 
 moving onwards with the vessel in the direction A C, so that 
 in the time which the body would take to fall to the deck, 
 the top of the mast would move from A to C. But the body, 
 being on the mast at the moment it is disengaged, has this 
 motion A C in common with the mast; and, therefore, in its 
 descent it is affected by two motions, viz. that of the vessel 
 expressed by A C, and its descending motion expressed by 
 A B. Hence, by the composition of motion, it will be found 
 at the opposite angle D of the parallelogram, at the end. of 
 
 5 
 
60 THE ELEMENTS OF MECHANICS. CHAP. V 
 
 the fall. During the fall, however, the mast has moved with 
 the vessel, and has advanced to C D, so that the body falls at 
 the foot of the mast. 
 
 (88.) An instance of the composition of motion, which is 
 worthy of some attention, as it affords a proof of the diurnal 
 motion of the earth, is derived from observing the descent 
 of a body from a very high tower. To render the explana- 
 tion of this more simple, we shall suppose the tower to be on 
 the equator of the earth. Let E P Q,Jig. 18., be a section 
 of the earth through the equator, and let P T be the tower. 
 Let us suppose that the earth moves on its axis in the direc- 
 tion E P Q. The foot P of the tower will, therefore, in one 
 day, move over the circle E P Q,, while the top T moves over 
 the greater circle T T' R. Hence it is evident, that the top 
 of the tower moves with greater speed than the foot, and 
 therefore in the same time moves through a greater space. 
 Now suppose a body placed at the top ; it participates in the mo- 
 tion which the top of the tower has in common with the earth. 
 If it be disengaged, it also receives the descending motion 
 T P. Let us suppose that the body would take five sec- 
 onds to fall from T to P, and that in the same time the top 
 T is moved by the rotation of the earth from T to T', the 
 foot being moved from P to P'. The falling body is therefore 
 endued with two motions, one expressed by T T', and the 
 other by T P. The combined effect of tltese will be found 
 in the usual way by the parallelogram. Take T p equal to 
 T T', the body will move from T top in the time of the fall, 
 and will meet the ground at p. But since T T' is greater 
 than P P 7 , it follows that the pointy must be at a distance 
 from P' equal to the excess of T T' above P P 7 . Hence the 
 body will not fall exactly at the foot of the tower, but at a 
 certain distance from it, in the direction of the earth's mo- 
 tion, that is, eastward. This is found, by experiment, to be 
 actually the case ; and the distance from the foot of the 
 tower, at which the body is observed to fall, agrees with that 
 which is computed from the motion of the earth, to as great 
 a degree of exactness as could be expected from the nature 
 of the experiment. 
 
 (89.) The properties of compounded motions cause some 
 of the equestrian feats exhibited at public spectacles to be 
 performed by a kind of exertion very different from that the 
 spectators generally attribute to the performer. For exam- 
 ple, the horseman, standing on the saddle, leaps over a garter 
 

 CHAP. V. FAMILIAR EXAMPLES. 51 
 
 extended over the horse at right angles to his motion ; the 
 horse passing under the garter, the rider lights upon the sad- 
 dle at the opposite side. The exertion of the performer, in 
 this case, is not that which he would use were he to leap 
 from the ground over a garter at the same height. In the 
 latter case, he would make an exertion to rise, and at the 
 same time to project his body forward. In the case, however, 
 of the horseman, he merely makes that exertion which is 
 necessary to rise directly upwards to a sufficient height to 
 clear the garter. The motion which he has in common with 
 the horse, compounded with the elevation acquired by his 
 muscular power, accomplishes the leap. 
 
 To explain this more fully, let A B C, j%. 19., be the di- 
 rection in which the horse moves, A being the point at which 
 the rider quits the saddle, and C the point at which he 
 returns to it. Let D be the highest point which is to be 
 cleared in tha leap. At A the rider makes a leap towards 
 the point E, and this must be done at such a distance from B, 
 that he would rise from B to E in the time in which the horse 
 moves from A to B. On departing from A, the rider has, 
 therefore, two motions, represented by the lines A E and 
 A B, by which he will move from the point A to the opposite 
 angle D of the parallelogram. At D, the exertion of the 
 leap being overcome by the weight of his body, he begins to 
 return downward, and would fall from D to B in the time in 
 which the horse moves from B to C. But at D he still 
 retains the motion which he had in common with the horse : 
 and, therefore, in leaving the point D, he has two motions, 
 expressed by the lines D F and D B. The compounded 
 effects of these motions carry him from D to C. Strictly 
 speaking, his motion from A to D, and from D to C, is not 
 in straight lines, but in a curve. It is not necessary here, 
 however, to attend to this circumstance. 
 
 (90.) If a billiard-ball strike the cushion of the table 
 obliquely, it will be reflected from it in a certain direction, 
 forming an angle with the direction in which it struck it. 
 This affords an example of the resolution and composition of 
 motion. We shall first consider the effect which would 
 ensue if the ball struck the cushion perpendicularly. 
 
 Let A B, jig. 20., be the cushion, and C D the direction 
 in which the ball moves towards it. If the ball and the 
 cushion were perfectly inelastic, the resistance of the cushion 
 would destroy the motion of the ball, and it would be reduced 
 
5*4 THE ELEMENTS OP MECHANICS. CHAP. V. 
 
 to a state of rest at D. If, on the other hand, the ball were 
 perfectly elastic, it would be reflected from the cushion, and 
 would receive as much motion from D to C, after the im- 
 pact, as it had from C to D before it. Perfect elasticity, 
 however, is a quality which is never found in these bodies. 
 They are always elastic, but imperfectly so. Consequently, 
 the ball, after the impact, will be reflected from D towards 
 
 C, but with a less motion than that with which it approach- 
 ed from C to D. 
 
 Now let us suppose that the ball, instead of moving from 
 C to D, moves from E to D. The force with which it strikes 
 
 D, being expressed by D E', equal to E D, may be resolved 
 into two, D F and D C'. The resistance of the cushion de- 
 stroys D C 7 , and the elasticity produces a contrary force in 
 the direction D C, but less than D C or D C', because that 
 elasticity is imperfect. The line D C expressing the force 
 in the direction C D, let D G (less than D C) express the 
 reflective force in the direction D C. The other element, 
 D F, into which the force D E' is resolved by the impact, is 
 not destroyed or modified by the cushion, and therefore, on 
 leaving the cushion at. D, the ball is influenced by two forces, 
 D F (which is equal to C E) and D G. Consequently it 
 will move in the diagonal D H. 
 
 (91.) The angle E D C is, in this case, called the " angle 
 of incidence," and C D H is called " the angle of reflec- 
 tion." It is evident, from what has been just inferred, that, 
 the ball being imperfectly elastic, the angle of incidence 
 must always be less than the angle of reflection, and, with 
 the same obliquity of incidence, the more imperfect the elas- 
 ticity is, the less will be the angle of reflection. 
 
 In the impact of a perfectly elastic body, the angle of re- 
 flection would be equal to the angle of incidence. For then 
 the line D G, expressing the reflective force, would be taken 
 equal to C D, and the angle C D H would be equal to C D E. 
 This is found by experiment to be the case when light is 
 reflected from a polished surface of glass or metal. 
 
 Motion is sometimes distinguished into absolute and relative. 
 What "relative motion" means is easily explained. If a 
 man walk upon the deck of a ship from stem to stern, he 
 has a relative motion which is measured by the space upon 
 the deck over which he walks in a given time. But while 
 he is thus walking from stem to stern, the ship and its con- 
 tents, including himself, are impelled through the deep iu 
 
CHAP. VI. 
 
 ATTRACTION. 53 
 
 the opposite direction. If it so happen that the motion of 
 the man from stem to stern be exactly equal to the motion 
 of the ship in the contrary way, the man will be, relatively 
 to the surface of the sea and that of the earth, at rest. Thus, 
 relatively to the ship, he is in motion, while, relatively to the 
 surface of the earth, he is at rest. But "still this is not abso- 
 lute rest. The surface itself is moving by the diurnal rota- 
 tion of the earth upon its axis, as well as by the animal 
 motion in its orbit round the sun. These motions, and 
 others to which the earth is subject, must be all compounded 
 by the theorem of the parallelogram of forces, before we can 
 obtain the absolute state of the body with respect to motion 
 or rest. 
 
 
 CHAPTER VI. 
 
 ATTRACTION. 
 
 (92.) WHATEVER produces, or tends to produce, a change 
 in the state of a particle or mass of matter with respect to 
 motion or rest, is a force. Rest, or uniform rectilinear mo- 
 tion, are therefore the only states in which any body can 
 exist which is riot subject to the present action of some force. 
 We are not, however, entitled to conclude, that because a 
 body is observed in one or other of these states, it is therefore 
 uninfluenced by any forces. It may be under the immedi- 
 ate action of forces which neutralize each other ; thus two 
 forces may be acting upon it which are equal, and in oppo- 
 site directions. In such a case, its state of rest, or of uniform 
 rectilinear motion will be undisturbed. The state of uni- 
 form rectilinear motion declares more with respect to the body 
 than the state of rest ; for the former betrays the action of a 
 force upon the body at some antecedent period ; this action 
 having been suspended, while .its effect continues to be ob- 
 served in the motion which it has produced. 
 
 (93.) When the state of a body is changed from rest to 
 uniform rectilinear motion, the action of the force is only 
 momentary, in which case it is called an impulse. If a body 
 in uniform rectilinear motion receive an impulse in the direc- 
 tion in which it is moving, the effect will be, that it will 
 continue to move uniformly in the same direction, but its 
 
54 THE ELEMENTS OF MECHANICS. CHAP. VI 
 
 velocity will be increased by the amount of speed which 
 the impulse would have given it, had it been previously 
 quiescent. Thus, if the previous motion be at the rate of ten 
 feet in a second, and the impulse be such as would move it 
 from a state of res.t at five feet in a second, the velocity, 
 after the impulse, will be fifteen feet in a second. 
 
 But if the impulse be received in a direction immediately 
 opposed to the previous motion, then it will diminish the 
 speed by that amount of velocity which it would give to the 
 body had it been previously at rest. In the example already 
 given, if the impulse were opposed to the previous motion, 
 the velocity of the body after the impulse would be five feet 
 in a second. If the impulse received in the direction opposed 
 to the motion be such as would give to the body at rest a 
 velocity equal to that with which it is moving, then the effect will 
 be, that after the impulse no motion will exist ; and if the 
 impulse would give it a still greater velocity, the body will be 
 moved in the opposite direction with an uniform velocity 
 equal to the excess of that due to the impulse over that which 
 the body previously had. 
 
 When a body in a state of uniform motion receives an 
 impulse in a direction not. coinciding with that of its motion, 
 it will move uniformly, after the impulse, in an intermediate 
 direction, which may be determined by the principles estab- 
 lished for the composition of motion in the last chapter. 
 
 Thus it. appears, that whenever the state of a body is 
 changed, either from rest to uniform rectilinear motion, or 
 rice, versa, or from one state of uniform rectilinear motion 
 to another, differng from that, eithjer in velocity or direction, 
 or in both, the phenomenon is produced by that peculiar 
 modification of force whose action continues but for a single 
 instant, and which has been called an impulse. 
 
 (94.) In most cases, however, the mechanical state of a 
 body is observed to be subject to a continual change or ten- 
 dency to change. We are surrounded by innumerable ex- 
 amples of this. A body is placed on the table. A continual 
 pressure is excited on the surface of the table. This pressure 
 is only the consequence of the continual tendency of the 
 body to move downwards. If the body were excited by a 
 force of the nature of an impulse, the effect upon the table- 
 would be instantaneous, and would immediately cease. It 
 would, in fact, be a blow. But the continuation of the pres- 
 sure proves the continuation of the action of the force. 
 
CHAP. VI. ATTRACTION, 55 
 
 If the table he removed from beneath the body, the force 
 which excites it, being no longer resisted, will produce motion; 
 it is manifested, not as before, by a tendency to produce 
 motion, but by the actual exhibition of that phenomenon. 
 Now, if the exciting force were an impulse, the body would 
 descend to the ground with an uniform velocity. On the 
 other hand, as will hereafter appear, every moment of its fall 
 increases its speed, and that speed is greatest at the instant 
 it meets the ground. 
 
 A piece of iron placed at a distance from a magnet ap- 
 proaches it, but not with an uniform velocity. The force 
 of the magnet continues to act. during the approach of the 
 iron, and each moment gives it increased motion. 
 
 (95.) The forces which are thus in constant operation, 
 proceed from secret agencies which the human mind has 
 novcr !:vm able to detect. All the analogies of nature prove 
 that they are not the immediate results of the divine will, 
 but are secondary causes, that is, effects of some more remote 
 principles. To ascend to these secondary causes, and thus, 
 as it were, approach one step nearer to the Creator, is the 
 great business of philosophy ; and the most certain means 
 ior accomplishing this, is diligently to observe, to compare, 
 and to classify the phenomena, and to avoid assuming the ex- 
 istence of any thing which has not either been directly ob- 
 served, or which cannot be inferred demonstratively from 
 natural phenomena. Philosophy should follow nature, and 
 not lead her. 
 
 While the law of inertia, established by observation and 
 reason, declares the inability of matter, from any principle 
 resident in it, to change its state, all the phenomena of the 
 universe prove that state to be in constant but regular fluc- 
 tuation. There is not in existence a single instance of the 
 phenomenon of absolute rest, or of motion which is absolutely 
 uniform and rectilinear. In bodies, or the parts of bodies, 
 there is no known instance of simple passive juxtaposition 
 unaccompanied by pressure or tension, or some other " ten- 
 dency to motion." Innumerable secret powers are ever at 
 work, compensating, as it were, for inertia, and supplying 
 the material world with a substitute for the principles of 
 action and will, which give such immeasurable superiority to 
 the character of life. 
 
 (9(3.) The forces which are thus in continual operation, 
 whose existence is demonstrated by their observed effects, 
 
56 THE ELEMENTS OF MECHANICS. CHAP. VI. 
 
 but whose nature, seat, and mode of operation, are unknown 
 to us, are called by the general name attractions. These 
 forces are classified according to the analogies which prevail 
 among their effects, in the same manner, and according to 
 the same principles, as organized beings are grouped in natu- 
 ral history. In that department of natural science, when 
 individuals are distributed in classes, the object is merely 
 to generalize, and thereby promote the enlargement of knowl- 
 edge ; but nothing is or ought to be thus assumed respecting 
 the essence, or real internal constitution of the individuals. 
 According to their external and observable characters and 
 qualities they are classed; aud this classification should never 
 be adduced as an evidence of any thing except that similitude 
 of qualities to which it owed its origin. 
 
 Phenomena are to the natural philosopher what organized 
 beings are to the naturalist. He groups and classifies them 
 on the same principles, and with a like object. And as the. 
 naturalist gives to each species a name applicable to the 
 individual beings which exhibit corresponding qualities, so 
 the philosopher gives to each force or attraction a name cor- 
 responding to the phenomena of wliicb it is the cause. The 
 naturalist is ignorant of the real essence or internal constitu- 
 tion of the thing which he nominates, and of lae manner in 
 which it comes to possess or exhibit those qualities which 
 form the basis of his classification ; and the natural philoso- 
 pher is equally ignorant of the nature, seat, and mode of 
 operation of the force which he assigns as the cause of an 
 observed class of effects. 
 
 These observations respecting the true import of the term 
 " attraction" seem the more necessary to be premised, be- 
 cause the general phraseology of physical science, taken as 
 language is commonly received, will seem to convey some- 
 thing more. The names of the several attractions which we 
 shall have to notice, frequently refer the seat of the cause 
 to specific objects, and seem to imply something respecting 
 its mode of operation. Thus, when we say, " the magnet 
 attracts a piece of iron," the true philosophical import of the 
 words is, " that a piece of iron, placed in the vicinity of the 
 magnet, will move towards it, or, placed in contact, will 
 adhere to it, so that some force is necessary to separate them." 
 In the ordinary sense, however, something more than this 
 simple fact is implied. It is insinuated that the magnet is 
 the seat of the force which gives motion to the iron ; that, 
 

 CILVP. Vf. ATTRACTION. 57 
 
 in the production of the phenomenon, the magnet is an agent 
 exerting a certain influence, of which the iron is the subject. 
 Of all this, however, there is no proof; on the contrary, since 
 the magnet must move towards the iron with just as much 
 force as the iron moves towards the magnet, there is as much 
 reason to place the seat of the force in the iron, and consider 
 it as an ^igent affecting the magnet. But, in fact, the influ- 
 ence which produces this phenomenon may not be resident 
 in either the one body or the other. It may be imagined to 
 be a property of a medium in which both are placed, or to 
 arise from some third body, the presence of which is not im- 
 mediately observed. However attractive these and like spec- 
 ulations may be, they cannot be allowed a place in physical 
 investigations, nor should consequences drawn from such 
 hypotheses be allowed to taint our conclusions with their un- 
 certainty. 
 
 The student ought, therefore, to be aware, that whatever 
 may seem to be implied by the language used in this science 
 in relation to attractions, nothing is permitted to form the 
 basis of reasoning respecting them except their effects ; and 
 whatever be the common signification of the terms used, 
 it is to these effects, and to these alone, they should be re- 
 ferred. 
 
 (97.) Attractions may be primarily distributed into two 
 classes ; one consisting of those which exist between the 
 molecules or constituent parts of bodies, and the other be- 
 tween bodies themselves. The former are sometimes called, 
 for distinction, molc.c.ular or atomic attractions. 
 
 Without the agency of molecular forces, the whole face 
 of nature would be deprived of variety and beauty ; the uni- 
 verse would be a confused heap of material atoms dispersed 
 through spa*-e, without form, shape, coherence, or motion. 
 Bodies would neither have the forms of solid, liquid, or air ; 
 heat and light would no longer produce their wonted effects ; 
 organized beings could not exist ; life itself, as connected 
 with body, would be extinct. Atoms of matter, whether dis- 
 tant or in juxtaposition, would have no tendency to change 
 their places, and all would be eternal stillness and rest. If, 
 then, we are asked for a proof of the existence of molecular 
 forces, we may point to the earth and to the heavens ; we 
 may name every object which can be seen or felt. The 
 whole material world is one great result of the influence of 
 these powerful agents. 
 
58 THE ELEMENTS OF MECHANICS. CHAP. VI. 
 
 (98.) It has been proved (11. et srq.) that the constituent 
 particles of bodies are of inconceivable minuteness, and that 
 they are not in immediate contact (26), but separated from 
 each other by interstitial spaces, which, like the atoms them- 
 selves, although too small to be directly observed, yet are 
 incontestably proved to exist, by observable phenomena, from 
 which their existence demonstratively follows. The resist- 
 ance which every body opposes to compression, proves that a 
 repulsive influence prevails between the particles, and* that 
 this repulsion is the cause which keeps the atoms separate, 
 and maintains the interstitial space just mentioned. Although 
 this repulsion is found to exist between the molecules of all 
 substances whatever, yet it has different degrees of energy in 
 different bodies. This is proved by the fact, that some sub- 
 stances admit of easy compression, while, in others, the exer- 
 tion of considerable force is necessary to produce the smallest 
 diminution in bulk. 
 
 The space around each atom of a body, through which 
 this repulsive influence extends, is generally limited, and 
 immediately beyond it, a force of the opposite kind is mani- 
 fested, viz. attraction. Thus, in solid bodies, the particles 
 resist separation as well as compression, and the application 
 of force is as necessary to break the body, or divide it into 
 separate parts, as to force its particles into closer aggregation. 
 It is by virtue of this attraction that solid bodies maintain 
 their figure, and that their parts are not separated and scat- 
 tered like those of fluids, merely by their own weight. This 
 force is called the attraction of cohesion. 
 
 The cohesive force acts in different substances with differ- 
 out degrees of energy : in some its intensity is very great, 
 but the sphere of its influence apparently very limited. This 
 is the case with all bodies which are hard, strong, and brittle, 
 which no force can extend or stretch in any perceptible de- 
 gree, and which require a great force to break or tear them 
 usunder. Such, for example, is cast iron, certain stones, 
 and various other substances. In some bodies, the cohesive 
 force is weak, but the sphere of its action considerable. Bod- 
 ies which are easily extended, without being broken or torn 
 asunder, furnish examples of this. Such are Indian-rubber, 
 or caoutchouc, several animal and vegetable products, and, 
 in general, all solids of a soft and viscid kind. 
 
 Between these extremes, the cohesive force may be ob- 
 served in various decrees. In lead and other soft metals, 
 
CHAP. VI. COHESION. 59 
 
 its sphere of action is greater, and its energy less, than in the 
 former examples ; but its sphere less, and energy greater, 
 than in the latter ones. It is from the influence of this force, 
 and that of the repulsion, whose sphere of action is still closer 
 to the component atoms, that all the varieties of form which 
 we denominate hard, soft, tough, brittle, ductile, pliant, &/c. 
 arise. 
 
 After having been broken, or otherwise separated, the 
 parts of a solid may bo again united by their cohesion, pro- 
 vided any considerable number of points be brought into suf- 
 ficiently close contact. When this is done by mechanical 
 means, however, the cohesion is not so strong as before their 
 separation, and a comparatively small force will be sufficient 
 again to disunite them. Two pieces of lead freshly cut, with 
 smooth surfaces, will adhere when pressed together, and will 
 require a considerable force to separate them. In the same 
 manner, if a piece of Indian-rubber be torn, the parts sepa- 
 rated will again cohere, by being brought together with a 
 slight pressure. The union of the parts, in such instances, 
 is easy, because the sphere through which the influence of 
 cohesion extends is considerable ; but even in bodies in which 
 this influence extends through a more limited space, the co- 
 hesion of separate pieces will be manifested, provided their 
 surfaces be highly polished, so as to insure the near approach 
 of a great number of their particles. Thus two polished 
 surfaces of glass, metal, or stone, will adhere when brought 
 into contact. 
 
 In all these cases, if the bodies be disunited by mechanical 
 force, they will separate at exactly the parts at which they 
 had been united, so that, after their separation, no part of the 
 one will adhere to the other ; proving that the force of cohe- 
 sion of the surfaces brought into contact is less than that 
 which naturally held the particles of each together. 
 
 (99.) When a body is in the liquid form, the weight of its 
 particles greatly predominates over their mutual cohesion, 
 and, consequently, if such a body be uncontined, it will be 
 scattered by its own weight ; if it be placed in any vessel, 
 it will settle itself, by the force of its weight, into the lowest 
 parts, so that no space in the vessel below the upper surface 
 of the liquid will be unoccupied. The particles of a solid 
 body placed in the vessel have exactly the same tendency, 
 by reason of their weight ; but this tendency is resisted and 
 prevented from taking effect by their strong cohesion. 
 
 
60 THE ELEMENTS OF MECHANICS. CHAP. VI 
 
 Although this cohesion in solids is much greater than in 
 liquids, and productive of more obvious effects, yet the prin- 
 ciple is not altogether unobserved in liquids. Water convert- 
 ed into vapor by heat, is divided into inconceivably minute 
 particles, which ascend in the atmosphere. When it is there 
 deprived of a part of that heat which gave it the vaporous 
 form, the particles, in virtue of their cohesive force, collect 
 into round drops, in which form they descend to the earth. 
 
 In the same manner, if a liquid be allowed to fall gradu- 
 ally from the lip of a vessel, it will not be dismissed in parti- 
 cles indefinitely small, as if its mass were incoherent, like 
 sand or powder, but will fall in drops of considerable magni- 
 tude. In proportion as the cohesive force is greater, these 
 drops affect a greater size. Thus, oil and viscid liquids fall 
 in large drops ; ether, alcohol, and others, in small ones. 
 
 Two drops of rain trickling down a window pane will 
 coalesce when they approach each other ; and the same phe- 
 nomenon is still more remarkable, if a few drops of quick- 
 silver be scattered on an horizontal plate of glass. 
 
 It is the cohesive principle which gives rotundity to grains 
 of shot : the liquid metal is allowed to fall like rain from a 
 great elevation. In its descent, the drops become truly glob- 
 ular, and before they reach the end of their fall, they are 
 hardened by cooling, so that they retain their shape. 
 
 It is also, probably, to the cohesive attraction that we 
 should assign the globular forms of all the great bodies of 
 the universe ; the sun, planets, satellites, &c., which origi- 
 nally may have been in the liquid state. 
 
 (100.) Molecular attraction is also exhibited between the 
 particles of liquids and solids. A drop of water will not 
 descend freely when it is in contact with a perpendicular 
 glass plane : it will adhere to the glass ; its descent will be 
 retarded ; and if its weight be insufficient to overcome the 
 adhesive force, it will remain suspended. 
 
 If a plate of glass be placed upon the surface of water 
 without being permitted to sink, it will require more force to 
 raise it from the water than is sufficient merely to balance the 
 weight of the glass. This shows the adhesion of the water 
 and glass, and also the cohesive force with which the particles 
 of the water resist separation. 
 
 If a needle be dipped in certain liquids, a drop will remain 
 suspended at its point when withdrawn from them : and, in 
 general, when a solid body has been immersed in a liquid, and 
 

 CHAP. VI. MOLECULAR ATTRACTION. 61 
 
 withdrawn, it is wet; that is, some of the liquid has adhered 
 to its surfaces. If no attraction existed between the solid 
 and liquid, the solid would be in the same state after immer- 
 sion as before. This is proved by liquids and solids between 
 which no attraction exists. If a piece of glass be immersed 
 in mercury, it will be in the same state when withdrawn as 
 before it was immersed. No mercury will adhere to it ; it will 
 not be wet. 
 
 When it rains, the person and vesture are affected only be- 
 cause this attraction exists between them and water. If it 
 rained mercury, none would adhere to them. 
 
 (101.) When molecular attraction is exhibited by liquids 
 pervading the interstices of porous bodies, ascending in crev- 
 ices or in the bores of small tubes, it is called capillary at- 
 traction. Instances of this are innumerable. Liquids are 
 thus drawn into the pores of sponge, sugar, lamp-wick, &c. 
 The animal and vegetable kingdom furnish numerous exam- 
 ples of this class of effects. 
 
 A weight, being suspended by a dry rope, will be drawn 
 upwards through a considerable height, if the rope be moist- 
 ened with a wet sponge. The attraction of the particles com- 
 posing the rope for those of the water is in this case so power- 
 ful, that the tension produced by several hundred weight can- 
 not expel them. 
 
 A glass tube, of small bore, being dipped in water tinged 
 by mixture with a little ink, will retain a quantity of the liquid 
 suspended when withdrawn. The height of the liquid in the 
 tube will be seen by looking through it. It is found that the 
 less the bore of the tube is, the greater will be the height of 
 the column sustained. A series of such tubes fixed in the 
 same frame, with their lower orifices at the same level, and 
 with bores gradually decreasing, being dipped in the liquid, 
 will exhibit columns gradually increasing. 
 
 A capillary syphon is formed of a hank of cotton threads, 
 one end of which is immersed in the vessel containing the 
 liquid, and the other is carried into the vessel into which the 
 liquid is to be transferred. The liquid may be thus drawn 
 from the one vessel into the other. The same effect may be 
 produced by a glass syphon with a small bore. 
 
 (102.) It frequently happens that a molecular repulsion is 
 
 exhibited between a solid and a liquid. If a piece of wood 
 
 be immersed in quicksilver, the liquid will be depressed at 
 
 that part of the surface which is near the wood ; and in like 
 
 6 
 
62 THE ELEMENTS OF MECHANICS. CHAP. VI. 
 
 manner, if it be contained in a glass vessel, it will be depress- 
 ed at the edges. In a barometer tube, the surface of the 
 mercury is convex, owing partly to the repulsion between the 
 glass and mercury. 
 
 All solids, however, do not repel mercury. If any golden 
 trinket be dipped in that liquid, or even be exposed for a mo- 
 ment to contact with it, the gold will be instantly intermingled 
 with particles of quicksilver, the metal changes its color, and 
 becomes white like silver, and the mercury can only be extri- 
 cated by a difficult process. Chains, seals, rings, &,c., should 
 always be laid aside by those engaged in experiments or other 
 processes in which mercury is used. 
 
 (103.) Of all the forms under which molecular force is ex- 
 hibited, that in which it takes the name of affinity is attend- 
 ed with the most conspicuous eifects. Affinity is in chemis- 
 try what inertia is in mechanics the basis of the science. 
 The present treatise is not the proper place for any detailed 
 account of this important class of natural phenomena. Those 
 who seek such knowledge are referred to our treatise on 
 CHEMISTRY. Since, however, affinity sometimes influences 
 the mechanical state of bodies, and affects their mechanical 
 properties, it will be necessary here to state so much respect- 
 ing it as to render intelligible those references which we may 
 have occasion to make to such effects. 
 
 When the particles of different bodies are brought intc 
 close contact, and more especially when, being in a fluid 
 state, they are mixed together, their union is frequently ob- 
 served to produce a compound body, differing in its qualities 
 from either of the component bodies. Thus the bulk of the 
 compound is often greater or less than the united volumes of 
 the component bodies. The component bodies may be of 
 the ordinary temperature of the atmosphere, and yet the com- 
 pound may be of a much higher or lower temperature. The 
 components may be liquid, and the compound solid. The 
 color of the compound may bear no resemblance whatever to 
 that of the components. The species of molecular action be- 
 tween the component?:, which produce these and similar ef- 
 fects, is called affinity. 
 
 (104.) We shall limit ourselves here to the statement of a 
 few examples of these phenomena. 
 
 If a pint of water and a pint of sulphuric acid be mixed, 
 the compound will be considerably less than a quart. The 
 density of the mixture is, therefore, greater than that which 
 
CHAP. VI. AFFINITY. 63 
 
 would result from the mere diffusion of the particles of the one 
 fluid through those of the other. The particles have as- 
 sumed a greater proximity, and therefore exhibit a mutual 
 attraction. 
 
 In this experiment, although the liquids before being mixed 
 be of the temperature of the surrounding air, the mixture will 
 be so intensely hot, that the vessel which contains it cannot 
 be touched without pain. 
 
 If the two aeriform fluids, called oxygen and hydrogen, be 
 mixed together in a certain proportion, the compound will be 
 water. In this case, the components are different from the 
 compound, not merely in the one being air and the other 
 liquid, but in other respects not less striking. The com- 
 pound, water, extinguishes fire, and yet of the components, 
 hydrogen is one of the most inflammable substances in nature, 
 and the presence of oxygen is indispensably necessary to sus- 
 tain the phenomenon of combustion. 
 
 Oxygen gas, united with quicksilver, produces a compound 
 of a black color, the quicksilver being white and the gas 
 colorless. When these substances are combined in another 
 proportion, they give a red compound. 
 
 (105.) Having noticed the principal molecular forces, we 
 (shall now proceed to the consideration of those attractions 
 which are exhibited between bodies existing in masses. The 
 influence of molecular attractions is limited to insensible dis- 
 tances. On the contrary, the forces which are now to be 
 noticed, act at considerable distances, and to the influence 
 of some there is no limit, the effect, however, decreasing as 
 the distance increases. 
 
 The effect of the loadstone on iron is well known, and is 
 one of this class of forces. For a detailed account of this 
 force, and the various phenomena of which it is the cause, 
 the reader is referred to our treatise on MAGNETISM. 
 
 When glass, wax, amber, and other substances, are submit- 
 ted to friction with silken or woollen cloth, they are observed 
 to attract feathers, and other light bodies placed near them. 
 A like effect is produced in several other ways, and is attend- 
 ed with other phenomena, the discussion of which forms a 
 principal part of physical science. The force thus exhib- 
 ited is called electricity. For details respecting it, and for 
 its connection with magnetism, the reader is referred to our 
 treatises on ELECTRICITY and ELECTRO-MAGNETISM. 
 
 M06.) These attractions exist either between bodies of 
 
64 THE ELEMENTS OF MECHANICS. CHAP. VJ. 
 
 particular kinds, or are developed by reducing the bodies 
 which manifest them to a certain state by friction, or some 
 other means. There is, however, an attraction, which is 
 manifested between bodies of all species, and under all cir- 
 cumstances whatever ; an attraction, the intensity of which 
 is wholly independent of the nature of the bodies, and only 
 depends on their masses and mutual distances. Thus, if a 
 mass of metal and a mass of clay.be placed in the vast abyss 
 of space, at a mile asunder, they will instantly commence to 
 approach each other with certain velocities. Again, if a mass 
 of stone and of wood respectively equal to the former, be 
 placed at a like distance, they will also commence to approach 
 each other with the same velocities as the former. This 
 universal attraction, which only depends on the quantity of 
 the masses and their mutual distances, is called the " attrac- 
 tion of gravitation." We shall first explain the "law" of this 
 attraction, and shall then point out some of the principal phe- 
 nomena by which its existence and its law are known. 
 
 (107.) The "law of gravitation," sometimes, from its uni- 
 versality, called the " law of nature," rnay be explained as 
 follows : 
 
 Let us suppose two masses, A and B, in pure space, beyond 
 the influence or attraction of any other bodies, and placed in 
 a state of rest, at any proposed distance from each other. 
 By their mutual attraction they will approach each other, but 
 not with the same velocity. The velocity of A will be great- 
 er than that of B, in the same proportion as its mass is less 
 than that of B. Thus, if the mass of B be twice that of A, 
 while A approaches B through a space of two feet, B will 
 approach A through a space of one foot. Hence it follows, 
 that the force with which A moves towards B is equal to the 
 force with which B moves towards A (f>8). This is only a 
 consequence of the property of inertia, and is an example of 
 the equality of action and reaction, as explained in Chapter 
 IV. The velocity with which A and B approach each other 
 is estimated by the diminution of their distance, A B, by their 
 mutual approach in a given time. Thus, if in one second A 
 move towards B through a space of two feet, and in the same 
 time B move towards A through the space of one foot, they 
 will approach each other through a space of three feet in a 
 second, which will be their relative velocity (01). 
 
 If the mass of B be doubled, it will attract A with double 
 the former force, or, what is the same, will cause A to ap- 
 
CHAP. VI. GRAVITATION. 65 
 
 proach B with double the former velocity. If the mass of B 
 be trebled, it will attract A with treble the first force, and, in 
 general, while the distance A B remains the same, the attrac- 
 tive force of B upon A will increase or diminish in exactly 
 the same proportion as the mass of B is increased or dimin- 
 ished. 
 
 In the same manner, if the mass A be doubled, it will be 
 attracted by B with a double force, because B exerts the same 
 degree of attraction on every part of the mass A, arid any 
 addition which it may receive will not diminish or otherwise 
 affect the influence of B on its former mass. 
 
 Thus it is a general law of gravitation, that so long as the 
 distance between two bodies remains the same, each will at- 
 tract and be attracted by the other, in proportion to its mass ; 
 and any increase or decrease of the mass will cause a corre- 
 sponding increase or decrease in the amount of the attraction. 
 
 (108.) We shall now explain the law, according to which 
 the attraction is changed, by changing the distance between 
 the bodies. At the distance of one mile, the body B attracts 
 A with a certain force. At the distance of two miles, the 
 masses not being changed, the attraction of B upon A will 
 be one fourth of its amount at the distance of one mile. At 
 the distance of three miles, it will be one ninth of its original 
 amount; at four miles, it is reduced to a sixteenth, and so 
 on. The following table exhibits the diminution of the at- 
 traction corresponding to the successive increase of distance : 
 
 {Distance 
 
 1 
 
 1 ^ 
 
 I 
 
 1 4 | 
 
 5 
 
 1 
 
 1 7 
 
 1 
 
 | &,c. 
 
 Attraction 
 
 1 
 
 l * 
 
 l * 
 
 IA 1 
 
 A 
 
 1 A 
 
 IA 
 
 IA 
 
 | &.C. 
 
 In ARITHMETIC, that number which is found by multiplying 
 any proposed number by itself, is called its square. Thus 4, 
 that is, 2 multiplied by 2, is the square of 2 ; 9, that is, 3 
 times 3, is the square of 3 ; and so on. On inspecting the 
 above table, it will be apparent, therefore, that the attraction 
 of gravitation decreases in the same proportion as the square 
 of the distance from the attracting body increases, the mass 
 of both bodies in this case being supposed to remain the 
 same; but if the mass of either be increased or diminished, 
 the attraction will be increased or diminished in the same 
 proportion. 
 
 (109.) Hence the low of nature may be thus expressed : 
 " The mutual attraction of two bodies increases in thft same* 
 C* 
 
THE ELEMENTS OF MECHANICS. CHAP. VI. 
 
 proportion as their masses are increased, and as the square of 
 their distance is decreased ; and it decreases in proportion as 
 their masses are decreased, and as the square of their distance 
 is increased." 
 
 (110.) Having explained the law of gravitation, we shall 
 now proceed to show how the existence of this force is prov- 
 ed, and its law discovered. 
 
 The earth is known to be a globular mass of matter, in- 
 comparably greater than any of the detached bodies which 
 are found upon its surface. If one of these bodies, suspend- 
 ed at any proposed height above the surface of the earth, be 
 disengaged, it will be observed to descend perpendicularly to 
 the earth, that is, in the direction of the earth's centre. The 
 force with which it descends will also be found to be in pro- 
 portion to the mass, without any regard to the species of the 
 body. These circumstances are consistent with the account 
 which we have given of gravitation. But by that account we 
 should expect, that as the falling body is attracted with a cer- 
 tain force towards the earth, the oarth itself should be attract- 
 ed towards it by the same force ; and instead of the falling 
 body moving towards the earth, which is the phenomenon 
 observed, the earth and it should move towards each other, 
 and meet at some Liter modi ate point. This, in fact, is the 
 ase, although it is impossible to render the motion of the 
 earth observable, for reasons which will easily be understood. 
 
 Since all the bodies around us participate in this motion, it 
 would not be directly observable, even though its quantity 
 were sufficiently great to be perceived under other circum- 
 stances. But, setting aside this consideration, the space 
 through which the earth moves in such a case is too minute to 
 be the subject of sensible observation. It has been stated 
 (107), that when two bodies attract each other, the space, 
 through which the greater approaches the lesser, bears to 
 that through which the lesser approaches the greater, the 
 same proportion as the mass of the lesser bears to the mass 
 of the greater. Now the mass of the earth is more than 
 1000,000,000,000,000 times the mass of any body which 
 is observed to fall on its surface ; and, therefore, if even 
 the largest body which can come under observation, were to 
 fall through an height of 500 feet, the corresponding mo- 
 tion of the earth would be through a space less than the 
 1000,000,000,000,000th part of 500 feet, which is less than 
 the 100,000,000,000th part of an inch. 
 
CHAP. VI. GRAVITATION. 67 
 
 The attraction between the earth and detached bodies on 
 its surface is not only exhibited by the descent of these 
 bodies when unsupported, but by their pressure when sup- 
 ported. This pressure is what is called weight. The phe- 
 nomena of weight, and the descent of heavy bodies, will be 
 fully investigated in the next chapter. 
 
 (111.) It is not alone by the direct fall of bodies, that the 
 gravitation of the earth is manifested. The curvilinear 
 motion of bodies projected in directions different from the 
 perpendicular, is a combination of the effects of the uniform 
 velocity which has been given to the projectile by the impulse 
 which it has received, and the accelerated velocity which it 
 receives from the earth's attraction. Suppose a body placed 
 at any point ,Jig. 21., above the surface of the earth, and 
 let P C be the direction of the earth's centre. If the body 
 were allowed to move without receiving any impulse, it would 
 descend to the earth in the direction P A, with an acceler- 
 ated motion. But suppose that, at the moment of its depart- 
 ure from P, it receives an impulse in the direction P B, 
 whicli would carry it to B in the time the body would fall 
 from P to A ; then, by the composition of motion, the body 
 must, at the end of that time, be found in the line B D, 
 parallel to P A. If the motion in the direction of P A were 
 uniform, the body P would, in this case, move in the straight 
 line from P to D. But this is not the case. The velocity 
 of the body in the direction P A is at first so small as to pro- 
 duce very little deflection of its motion from the line P B. 
 As the velocity, however, increases, this deflection increases, 
 so that it moves from P to D in a curve, which is convex to- 
 wards P B. 
 
 The greater the velocity of the projectile in the direction 
 P B, the greater sweep the curve will take. Thus it will suc- 
 cessively take the forms P D, P E, P F, &c. : and that veloci- 
 ty can be computed, which (setting aside the resistance of the 
 air) would cause the projectile to go completely round the 
 earth, and return to the point P from which it departed. In 
 thi$ case, the body P would continue to revolve round the 
 earth like the moon. Hence it is obvious, that the phenom- 
 enon of the revolution of the moon round the earth, is noth- 
 ing more than the combined effects of the earth's attraction, 
 and the impulse which it received when launched into space 
 by the hand of its Croator. 
 
Ob THE ELEMENTS OF MECHANICS. CHAP. VI. 
 
 (112.) This is a great step in the analysis of the phenom- 
 enon of gravitation. We have thus reduced to the same 
 class two effects apparently very dissimilar the rectilinear 
 descent of a heavy body, and the nearly circular revolution 
 of the moon round the earth. Hence we are conducted to 
 a generalization still more extensive. 
 
 As the moon's revolution round the earth, in an orbit 
 nearly circular, is caused by the combination of the earth's 
 attraction, and aa original projectile impulse, so also the 
 similar phenomena of the planets' revolution round the sun 
 in orbits nearly .circular, must be considered an effect of the 
 same class, as well as tihe revolution of the satellites of those 
 planets which are attended by such bodies. Although the 
 orbits in which die comets move, deviate very much from 
 circles, yet this does not hinder the application of the same 
 principle to them, their deviation from circles not depending 
 on the sun's attraction^ b.it only on the direction and force 
 of the original impulse which put them in motion. 
 
 (113.) We therefore conclude that gravitation is the 
 principle which, as it were, animates the universe. All the 
 great changes and revolutions of the bodies which compose 
 our system, can be graced to or derived from this principle. 
 It still remains to .show how that remarkable law, by which 
 his force is declared to increase or decrease in the same pro- 
 portion as the square of the distance from the attracting body 
 is decreased or increased, may l>e verified and established. 
 
 It has been shown, that the curvilinear path of a projectile 
 depends on, and can be derived, by mathematical reasoning, 
 from the consideration of the intensity of the earth's attrac- 
 tion, and the force of the original impulse, or the velocity of 
 projection. In the same manner, by a reverse process, when 
 we know the curve in which a projectile moves, we can in- 
 fer the amount of the attracting force which gives the curva- 
 ture to its path. In this way, from our knowledge of the 
 curvature of the moon's orbit, and the velocity with which 
 she moves, the intensity of the attraction which the earth 
 exerts upon her can be exactly ascertained. Upon compar- 
 ing this with the force of gravitation at the earth's surface, 
 it is found that the latter is as many times greater than the 
 former, as the square of the moon's distance is greater than 
 the square of the distance of a body on the surface of the 
 earth from its centre. 
 
CHAP. VI. LAW OF GRAVITATION. 
 
 (114.) If this were the only fact which could be brought 
 to establish the law of nature, it might bo thought to be an 
 accidental relation, not necessarily characterizing the at- 
 traction of gravitation. Upon examining the orbits and ve- 
 locities of the several planets, the same result is, however, 
 obtained. It is found that the forces with which they are 
 severally attracted by the sun are great, in exactly the same 
 proportion as the squares of the several numbers expressing 
 their distances are small. The mutual gravitation of bodies 
 on the surface of the earth towards each other is lost in the 
 predominating force exerted by the earth upon all of them. 
 Nevertheless, in some cases, this effect has not only been 
 observed, but actually measured. 
 
 A plumb-line, under ordinary circumstances, hangs in a 
 direction truly vertical ; but if it be near a large mass of 
 matter, as a mountain, it has been observed to be deflected 
 from the true vertical, towards the mountain. This effect 
 was observed by Dr. Maskeline near the mountain called 
 Skehallien, in Scotland, and by French astronomers near 
 Chimbora9O. For particulars of these observations, see our 
 treatise on GEODESY. 
 
 Cavendish succeeded in exhibiting the effects of the mutual 
 gravitation of metallic spheres. Two globes of lead A, B, 
 each about a foot in diameter, were placed at a certain dis- 
 tance asunder. A light rod, to the ends of which were 
 attached small metallic balls, G, D, was suspended at its 
 centre E from a fine wire, and the rod was placed as in 
 fig. 22., so that the attractions of each of the leaden globes 
 had a tendency to turn the rod round the centre E in the 
 same direction. A manifest effect was produced upon the 
 balls C, D, by the gravitation of the spheres. In this ex- 
 periment, care must be taken that no magnetic substance 
 is intermixed with the materials of the balls. 
 
 Having so far stated the principles on which the law of 
 gravitation is established, we shall dismiss this subject without 
 further details, since it more properly belongs to the subject 
 of PHYSICAL ASTRONOMY ; to which we refer the reader for 
 a complete demonstration of the law, and for the detailed 
 developement of its various and important consequences. 
 
70 THE ELEMENTS OF MECHANICS. CHAP. VII. 
 
 CHAPTER VII. 
 
 TERRESTRIAL GRAVITY 
 
 - 
 
 (115.) GRAVITATION is the general name given to this 
 attraction, by whatever masses of matter it may be manifested. 
 As exhibited in the effects produced by the earth upon sur- 
 rounding bodies, it is called " terrestrial gravity." 
 
 As the attraction of the earth is directed towards its centre, 
 it might be expected that two plumb-lines should appear not 
 to be parallel, but so inclined to each other as to converge to 
 a point under the surface of the earth. Thus, if A B and 
 C D,Jig. 23., be two plumb-lines, each will be directed to 
 the centre O, where, if their directions were continued, they 
 would meet. In ;like manner, if two bodies were allowed 
 to fall from A and C, they would descend in the directions 
 A B and C D, which converge to O. Observation, on the 
 contrary, shows that plumb-lines suspended in places not far 
 distant from each other are truly parallel ; and that bodies al- 
 lowed to fall, descend in parallel lines. This apparent paral- 
 lelism of the direction of terrestrial gravity is accounted for by 
 the enormous proportion which the magnitude of the earth 
 bears to the distance between the two plumb-lines or the twjD 
 falling bodies which are compared. If the distance betweeTT 
 the places B, D, were 1200 feet, the inclination of the lines 
 A B and C D would not amount, .to a quarter of a minute, or 
 fhe 240th part of a degree. But the distance, in cases where 
 the parallelism is assumed, is never greater than, and seldom 
 so great as, a few yards ; and hence the inclination of the 
 directions A B and C D is too small to be appreciated by any 
 practical measure. In the investigation of the phenomena 
 of falling bodies, we shall, therefore, assume that all the par- 
 ticles of the same body are attracted in parallel directions, 
 perpendicular to an horizontal plane. 
 
 (116.) Since the intensity of terrestrial gravity increases 
 as the square of the distance decreases, it might be expected 
 that, as a falling body approaches the earth, the force which 
 accelerates it should be continually increasing, and, strictly 
 speaking, it is so. But any height through which we observe 
 falling bodies to descend bears so very small a proportion to 
 the whole distance from the centre, that the change of inten- 
 sity of the force of gravitv is quite beyond any oractka! 
 9 
 
CHAP. VII. BODIES FALL WITH EQUAL SPEED. 71 
 
 means of estimating it. The radius, or the distance from the 
 surface of the earth to its centre, is 4000 miles. Now, sup- 
 pose a body descended through the height of half a mile, a 
 distance very much beyond those used in experimental in- 
 quiries ; the distances from the centre, at the beginning and 
 end of the fall, are then in the proportion of 8000 to 8001 , and 
 therefore the proportion of the force of attraction at the com- 
 mencement to the force at the end, being that of the squares 
 of these numbers, is 64,000,000 to 64,016,001, which, in the 
 whole descent, is an increase of about one part -in 4000; a 
 quantity practically insignificant. We shall, therefore, in 
 explaining the laws of falling bodies, assume that, in the 
 entire descent, the body is urged by a force of uniform in- 
 tensity. 
 
 Although the force which attracts all parts of the same 
 body during its descent in a given place is the same, yet the 
 force of gravity, at different parts of the earth's surface, has 
 different intensities. The intensity diminishes with the lati- 
 tude, so that it is greater towards the poles, and lesser to- 
 wards the equator. The causes of this variation, its law, and 
 the experimental proofs of it, will be explained when we 
 shall treat of centrifugal force, and the motion of pendulums 
 It is sufficient merely to advert to it in this place. 
 
 (117.) Since the earth's attraction acts separately and 
 equally on every particle of matter, without regard to the 
 nature or species of the body, it follows that all bodies, of 
 whatever kind, or whatever be their masses, must be moved 
 with the same velocity. If two equal particles of matter be 
 placed at a certain distance above the surface of the earth, 
 they will fall in parallel lines, and with exactly the same 
 speed, because the earth attracts them equally. In the same 
 manner, a thousand particles would fall with, equal velocities 
 Now, these circumstances will in no wise be changed, if 
 those 1000 particles, instead of existing separately, be aggre- 
 gated into two solid masses, one consisting of 990 particles, 
 and the other of 10. We shall thus have a heavy body and 
 a light one, and, according to our reasoning, they must fall 
 to the ear tli with the same speed. 
 
 Common experience, however, is not always consistent 
 with this doctrine. What are called light substances, as 
 feathers, gold-leaf, paper, &c., are observed to fall slowly and 
 irregularly, while heavier masses, as solid pieces of metal, 
 stones, &,c., fall rapidly. Nay, there are not a few instances 
 
 
72 THE ELEMENTS OF MECHANICS. CHAP. VII 
 
 in which the earth, instead of attracting bodies, seems to re 
 pel them, as in the case of smoke, vapors, balloons, and other 
 substances which actually ascend. We are to consider that 
 the mass of the earth is not the only agent engaged in these 
 phenomena. The earth is surrounded by an atmosphere 
 composed of an elastic or aeriform fluid. This atmosphere 
 has certain properties, which will be explained in our treatise 
 on PNEUMATICS, and which are the causes of the anomalous 
 circumstances alluded to. Light bodies rise in the atmos- 
 phere, for the same reason that a piece of cork rises from the 
 bottom of a vessel of water ; and other light bodies fall more 
 slowly than heavy ones, for the same reason that an egg in 
 water falls to the bottom more slowly than a leaden bullet. 
 This treatise is not the place to give a direct explanation of 
 these phenomena. It will be sufficient for our present pur- 
 pose to show, that, if there were no atmosphere, all bodies, 
 heavy and light, would fall at the same rate. This may easily 
 be accomplished by the aid of an air-pump. Having, by that 
 instrument, abstracted the air from a tall glass vessel, we are 
 enabled, by means of a wire passing air-tight through a hole 
 in the top, to let fall several bodies from the top of the ves- 
 sel to the bottom. These, whether they be feathers, paper, 
 gold-leaf, pieces of money, &/c., all descend with the same 
 speed, and strike the bottom at the same moment. 
 
 (118.) Every one who has seen a heavy body fall from a 
 height, has witnessed the fact that its velocity increases as it 
 approaches the ground. But if this were not observable by 
 the eye, it would be betrayed by the effects. It is well 
 known, that the force with which a body strikes the ground 
 increases with the height from whence it has fallen. This 
 force, however, is proportional to the velocity which it has at 
 the moment it meets the ground, and therefore this velocity 
 increases with the height. 
 
 When the observations on attraction in the last chapter 
 are well understood, it will be evident that the velocity which 
 a body has acquired in falling from any height, is the accu- 
 mulated effects of the attraction of terrestrial gravity during 
 the whole time of the fall. Each instant of the fall a new 
 impulse is given to the body, from which it receives addition- 
 al velocity ; and its final velocity is composed of the aggrega- 
 tion of all the small increments of velocity which are thus 
 communicated. As we are at present to suppose the intensi- 
 ty of the attraction invariable, it will follow that the velocity 
 
CHAP. VII. DESCENT OF HEAVY BODIES. 73 
 
 communicated to the body in each instant of time will be 
 the same, and therefore that the whole quantity of velocity 
 produced or accumulated at the end of any time is propor- 
 tional to the length of that time. Thus, if a certain velocity 
 be produced in a body having fallen for one second, twice 
 that velocity will be produced when it has fallen for two 
 seconds, thrice that velocity in three seconds, and so on. 
 Such is the fundamental principle or characteristic of uniform- 
 ly accelerated motion. 
 
 (119.) In examining the circumstances of the descent of a 
 body, the time of the fall, and the velocity at each instant of 
 that time, are not the only things to be attended to. The 
 spaces through which it falls in given intervals of time, count- 
 ed either from the commencement of its fall, or from any 
 proposed epoch of the descent, are equally important objects 
 of inquiry. To estimate the space in reference to the time 
 and the final velocity, we must consider that this space has 
 been moved through with varying speed. From a state of 
 rest at the beginning of the fall, the speed gradually increases 
 with the time, and the final velocity is greater still than that 
 which the J,ody had at any preceding instant during its de- 
 scent. We cannot, therefore, directly appreciate the space 
 moved through in this case by the time and final velocity. 
 But, as the velocity increases uniformly with the time, we 
 shall obtain the average speed, by finding that which the 
 body had in the middle of the interval which elapsed between 
 the beginning and end of the fall, and thus the space through 
 which the body has actually fallen is that through which it 
 # would move in the same time" with this average velocity uni- 
 formly continued. 
 
 But since the velocity which the body receives in any time, 
 counted from the beginning of its descent, is in the propor- 
 tion of that time, it follows that the velocity of the body after 
 half the whole time of descent is half the final velocity. 
 From whence it appears, that the height from which a body 
 falls in any proposed time is equal to the space through which 
 a body would move in the same time with half the final ve- 
 locity, and it is therefore equal to half the space which would 
 be moved through in the same time with the final velocity. 
 
 (120.) It follows, from this reasoning, that between the 
 three quantities, the height, the time, and the final velocity, 
 which enter into the investigation of the phenomena of fall- 
 ing bodies, there are two fixed relations : First] the time, 
 7 
 
74 THE ELEMENTS OF MECHANICS. CHAP. VII 
 
 counted from the beginning of the fall, and the final velocity, 
 are proportional the one to the other ; so that as one in- 
 creases, the other increases in the same proportion. Sec- 
 ondly, the height being equal to half the space which would 
 be moved through in the time of the fall, with thejinal veloci- 
 ty, must have a fixed proportion to these two quantities, viz. 
 the time and the final velocity, or must be proportional to the 
 product of the two numbers which express them. 
 
 But since the time is always proportional to the final ve- 
 locity, they may be expressed by equal numbers, and the 
 product of equal numbers is the square of either of them. 
 Hence the product of the numbers expressing the time and 
 final velocity is equivalent to the square of the number express- 
 ing the time, or to the square of the number expressing the 
 final velocity. Hence we infer, that the height is always 
 proportional to the square of the time of the fall, or to the 
 square of the final velocity. 
 
 (121.) The use of a few mathematical characters will ren- 
 der these results more distinct, even to students not conver- 
 sant with mathematical science. Let S express the height 
 from which the body falls, V the final velocity, and T the 
 time of the fall, and let the square of any of these quantities, 
 or rather of their numerical expressions, be signified by plac- 
 ing the figure 2 over them ; thus, T 2 or V 2 . The sign x 
 between two numbers signifies that they are to be multiplied 
 together. These being premised, the results of the reason- 
 ing in which we have been just engaged, may be expressed 
 as follows : 
 
 V increases proportionally with T 
 S - - - VXT 
 S T 2 
 
 s v 2 
 
 The theorems [3] and [4] follow from [1] and [2] ; for 
 since by [1] T is proportional to V, it may be put for V in 
 [2], and by this substitution V X T becomes T X T or T 2 . 
 In the same manner and for the same reason, V may be 
 put for T, by which V X T becomes V X V, or V 2 . 
 
 By these formularies, if the height through which a body 
 falls freely in one second be known, the height through 
 which it will fall in any proposed time may be computed. 
 For since the height is proportional to the square of the 
 time the height through which it will fall in two seconds will 
 
CHAP. VII. DESCENT OF HEAVY BODIES. 75 
 
 be four times that which it falls through in one second. In 
 three seconds it will fall through nine times that space ; in 
 four seconds, sixteen times ; mjive seconds, twenty-Jive times ; 
 and so on. The following, therefore, is a general rule to 
 find the height through which a body will fall in any given 
 time : " Reduce the given time to seconds, take the square 
 of the number of seconds in it, and multiply the height 
 through which a body falls in one second by that number ; 
 the result will be the height sought." 
 
 The following table exhibits the heights and correspond- 
 ing times as far as 10 seconds : 
 
 Time |1|2|3|4|5|6|7|8|9|10 
 
 Height | 1 | 4 9 | 16 | 25 | 36 | 49 | 64 | 81 | 100 
 
 
 Each unit in the numbers of the first row expresses a sec- 
 ond of time, arid each unit in those of the second row ex- 
 presses the height through which a body falls freely in a 
 second. 
 
 (122.) If a body fall continually for several successive 
 seconds, the spaces which it falls through in each succeeding 
 second have a remarkable relation among each other, which 
 may be easily deduced from the preceding table. Taking 
 the space moved through in the first second still as our unit, 
 four times that space will be moved through in the first two 
 seconds. Subtract from this 1, the space moved through 
 in the first second, and the remainder 3 is the space through 
 which the body falls in the second second. In like manner 
 if 4, the height fallen through in the first two seconds, be 
 subtracted from 9, the height fallen through in the first 
 three seconds, the remainder 5 will be the space fallen 
 through in the third second. To find the space fallen through 
 in the fourth second, subtract 9, the space fallen through 
 in the first three seconds, from 16, the space fallen through 
 in the first four seconds, and the result is 7, and so on. 
 
 It thus appears that if the space fallen through in the first 
 second be called 1, the spaces described in the second, third, 
 fourth, fifth, &/c. seconds, will be expressed by the odd num- 
 bers respectively, 3, 5, 7, 9, &c. This places in a striking 
 point of view the accelerated motion of a falling body, the 
 spaces moved through in each succeeding second being con- 
 tinually increased. 
 
 (123.) If velocity be estimated by the space through which 
 
76 THE ELEMENTS OF MECHANICS. CHAP. VII. 
 
 the body would move uniformly in one second, then the final 
 velocity of a body falling for one second will be 2 ; for with 
 that final velocity the body would in one second move through 
 twice the height through which it has fallen. 
 
 (124.) Since the final velocity increases in the same pro- 
 portion as the time, it follows that after two seconds it is 
 twice its amount after one, and after three seconds thrice 
 that, and so on. Thus the following table exhibits the final 
 velocities corresponding to the times of descent : 
 
 Time I 1 I 2 | 3 4|5|6|7|8|9 
 
 Final velocity | 2 | 4 | 6 | 8 | 10 | 12 14 | 16 | 18 | 20 
 
 The numbers in the second row express the spaces through 
 which a body with the final velocity would move in one 
 second, the unit being, as usual, the space through which a 
 body falls freely in one second. 
 
 (125.) Having thus developed theoretically the laws which 
 characterize the descent of bodies, falling freely by the force 
 of gravity, or by any other uniform force of the same kind, 
 it is necessary that we should show how these laws can be 
 exhibited by actual experiment. There are some circum- 
 stances attending the fall of heavy bodies which would ren- 
 der it difficult, if not impossible, to illustrate, by the direct 
 observation of this phenomenon, the properties which have 
 been explained in this chapter. A body falling freely by 
 the force of gravity, as we shall hereafter prove, descends 
 in one second of time through a height of about 16 feet ; 
 in two seconds, it would, therefore, fall through four times 
 that space, or 64 feet ; in three seconds, through 9 times 
 the height, or 144 feet ; and in four seconds, through 256 
 feet. In order, therefore, to be enabled to observe the phe- 
 nome.na for only four seconds, we should command an height 
 of at least 256 feet. But further ; the velocity at the end 
 of the first second would be at the rate of 32 feet per second ; 
 at the end of the second second, it would be 64 feet per 
 second ; and towards the end of the fall, it would be about 
 120 feet per second. It is evident that this great degree of 
 rapidity would be a serious impediment to accurate observa- 
 tion, even though we should be able to command the requi- 
 site height. 
 
 It occurred to Mr. George Attwood, a mathematician and 
 natural philosopher of the last century, that all the phenomena 
 
CHAP. vii. ATTWOOD'S MACHINE. 77 
 
 of falling bodies might be experimentally exhibited and ac- 
 curately observed, if a force of the same kind as gravity, viz. 
 an uniformly accelerating force, be used, but of a much less 
 intensity ; so that, while the motion continues to be governed 
 by the same laws, its quantity may be so much diminished, 
 that the final velocity, even after a descent of many seconds, 
 shall be so moderated as to admit of most deliberate and 
 exact observation. This being once accomplished, nothing 
 more would remain but to find the height through which 
 a body would fall in one second, or, what is the same, the 
 proportion of the force of gravity to the mitigated but uni- 
 formly by accelerating force thus substituted for it. 
 
 (136:) To realize this notion, Attwood constructed a 
 wheel turning on its axle with very little friction, and hav- 
 ing a groove on its edge to receive a string. Over this 
 wheel, and in the groove, he placed a fine silken cord, to 
 the ends of which were attached equal cylindrical weights. 
 Thus placed, the weights perfectly balance each other, and 
 no motion ensues. To one of the weights he then added 
 a small quantity, so as to give it a slight preponderance. 
 The loaded weight now began to descend, drawing up on 
 the other side the unloaded weight. The descent of the 
 loaded weight, under these circumstances, is a motion ex- 
 actly of the same kind as the descent of a heavy body 
 falling freely by the force of gravity ; that is, it increases 
 according to the same laws, though at a very diminished 
 rate. To explain this, suppose that the loaded weight de- 
 scends from a state of rest through one inch in a second ; 
 it will descend through 4 inches in two seconds, through 9 in 
 three, through 16 in four, and so on. Thus, in 20 seconds, 
 it would descend through 400 inches, or 33 feet 4 inches 
 a height which, if it were necessary, could easily be com- 
 manded. 
 
 It might, perhaps, be thought, that, since the weights sus- 
 pended at the ends of the thread are in equilibrium, and 
 therefore have no tendency either to move or to resist mo- 
 tion, the additional weight placed upon one of them ought to 
 descend as rapidly as it would if it were allowed to fall freely 
 and unconnected with them. It is very true that this weight 
 will receive from the attraction of the earth the same force 
 when placed upon one of the suspended weights, as it would 
 if it were disengaged from them ; but in the consequences 
 'which ensue, there is this difference. If it were unconncct- 
 7* 
 
78 THE ELEMENTS OF MECHANICS. CHAP. VII. 
 
 ed with the suspended weights, the whole force impressed 
 upon it would be expended in accelerating its descent ; but, 
 being connected with the equal weights which sustain each 
 other in equilibrium, by the silken cord passing over the 
 wheel, the force which is impressed upon the added weight 
 is expended, not, as before, in giving velocity to the added 
 weight alone, but to it together with the two equal weights 
 appended to the string, one of which descends with the added 
 weight, and the other rises on the opposite side of the wheel. 
 Hence, setting aside any effect which the wheel itself pro- 
 duces, the velocity of the descent must be lessened just in 
 proportion as the mass among which the impressed force is 
 to be distributed is increased ; and therefore the rate of the 
 fall bears to that of a body falling freely the same proportion 
 as the added weight bears to the sum of the masses of the 
 equal suspended weights and the added weight. Thus the 
 smaller the added weight is, and the greater the equal sus- 
 pended weights are, tire slower will the rate of descent be. 
 
 To render the circumstances of the fall conveniently ob- 
 servable, a vertical shaft (see ^'^.24.) is usually provided, 
 which is placed behind the descending weight. This pillar 
 is divided into inches and halves, and, of course, may be still 
 more minutely graduated, if necessary. A stage to receive 
 the falling weight is movable on this pillar, and capable of 
 being fixed in any proposed position by an adjusting screw. 
 A pendulum vibrating seconds, the beat of which ought to be 
 very audible, is placed near the observer. The loaded weight 
 being thus allowed to descend for any proposed time, or from 
 any required height, all the circumstances of the descent 
 may be accurately observed, and the several laws already 
 explained in this chapter may be experimentally verified. 
 
 (127.) The laws which govern the descent of bodies by 
 gravity, being reversed, will be applicable to the ascent of 
 bodies projected upwards. If a body be projected directly 
 upwards with any given velocity, it will rise to the height 
 from which it should have fallen to acquire that velocity. The 
 earth's attraction will, in this case, gradually deprive the 
 body of the velocity which is communicated to it at the mo- 
 ment at which it is projected. Consequently, the phenome- 
 non will be that of retarded motion. At each part of its 
 ascent, it will have the same velocity which it would have 
 if it descended to the same place from the highest point to 
 which it rises. Hence it is clear, that all the particulars 
 
 

 CHAP. VIII. MOTION ON INCLINED PLANES. 79 
 
 relative to the ascent of bodies may be immediately inferred 
 from those of their descent, and therefore this subject de- 
 mands no further notice. 
 
 To complete the investigation of the phenomena of falling 
 bodies, it would now only remain to explain the method of 
 ascertaining the exact height through which a body would 
 descend in one second, if unresisted by the atmosphere, or 
 any other disturbing cause. As the solution of this problem, 
 however, requires the aid of principles not yet explained, it 
 must for the present be postponed. 
 
 CHAPTER VIII. 
 
 OF THE MOTION OF BODIES ON INCLINED PLANES AND CURVES. 
 
 (128.) IN the last chapter, we investigated the phenomena 
 of bodies descending freely in the vertical direction, and de- 
 termined the laws which govern, not their motion alone, but 
 that of bodies urged by any uniformly accelerating force 
 whatever. We shall now consider some of the most ordinary 
 cases in which the free descent of bodies is impeded, and 
 the effects of their gravitation modified. 
 
 (129.) If a body, urged by any forces whatever, be placed 
 upon a hard, unyielding surface, it will evidently remain at 
 rest, if the resultant (76) of all the forces which are applied 
 to it be directed perpendicularly against the surface. In 
 this case, the effect produced is pressure, but no motion en- 
 'ues. If only one force act upon the body, it will remain a* 
 rest, provided the direction of that force be perpendicular to 
 the surface. 
 
 But the effect will be different, if the resultant of the 
 forces which are applied to the body be oblique to the sur- 
 face. In that case, this resultant, which, for simplicity, may 
 be taken as a single force, may be considered as mechanically 
 equivalent to two forces (76), one in the direction of the 
 surface, and the other perpendicular to it. The latter ele- 
 ment will be resisted, and will produce a pressure ; the former 
 will cause the body to move. This will perhaps be more 
 clearly apprehended by the aid of a diagram. 
 
 Let A B, Jig. 25., be the surface, and let P be a particle 
 of matter placed upon it, and urged by a force in the direo- 
 
80 THE ELEMENTS OP MECHANICS. CHAP. VIII. 
 
 tion P D, perpendicular to A B. It is manifest, that this 
 force can only press the particle P against A B, but cannot 
 give it any motion. 
 
 But let us suppose, that the force which urges P is in a 
 direction P F, oblique to A B. Taking P F as the diagonal 
 of a parallelogram, whose sides are P D and P C (74), the force 
 P F is mechanically equivalent to two forces, expressed by 
 the lines P D and P C. But P D, being perpendicular to A B, 
 produces pressure without motion, and P C, being in the 
 direction of A B, produces motion without pressure. Thus 
 the effect of the force P F is distributed between motion and 
 pressure in a certain proportion, which depends on the ol>- 
 liquity of its direction to that of the surface. The two ex- 
 treme cases are, 1. When it is in the direction of the surface ; 
 it then produces motion without pressure : and, 2. When 
 it is perpendicular to the surface ; it then produces pressure 
 without motion. In all intermediate directions, however, it 
 will produce both these effects. 
 
 (130.) It will be very apparent, that the more oblique the 
 direction of the force P F is to A B, the greater will be that 
 part of it which produces motion, and the less will that be 
 which produces pressure. This will be evident by inspecting 
 Jig. 26. In this figure, the line P F, which represents the 
 force, is equal to P F in Jig. 25. But P D, which expresses 
 the pressure, is less in Jig. 20. than in Jig. 25., while P C, 
 which expresses the motion, is greater. So long, then, a.s 
 the obliquity of the directions of the surface and the force 
 remain unchanged, so long will the distribution of the force 
 between motion and pressure remain the same ; and there- 
 fore, if the force itself remain the same, the parts of it which 
 produce motion and pressure will be respectively equal. 
 
 (131.) These general principles being understood, no dif- 
 ficulty can arise in applying them to the motion of bodies 
 urged on inclined planes or curves by the force of gravity. 
 If a body be placed on an unyielding horizontal plane, it 
 will remain at rest, producing a pressure on the plane equal 
 to the total amount of its weight. For, in this case, the force 
 which urges the body being that of terrestrial gravity, its 
 direction is vertical, and therefore perpendicular to the hori- 
 zontal plane. 
 
 But if the body P, Jig. 25., be placed upon a plane A B, 
 oblique to the direction of the force of gravity, then, accord- 
 ing to what has been proved (129), the weight of the body 
 
 
CHAP. VIII. MOTION ON INCLINED PLANES. 81 
 
 will be distributed into two parts, P C and P D ; one, P D, pro- 
 ducing a pressure on the plane A B, and the other, P C, produc- 
 ing motion down the plane. Since the obliquity of the perpen- 
 dicular direction P F of the weight to that of the plane A B 
 must be the same on whatever part of the plane the weight 
 may be placed, it follows (130), that the proportion P C of 
 the weight which urges the body down the plane, must be 
 the same throughout its whole descent. 
 
 (132.) Hence it may easily be inferred, that the force 
 down the plane is uniform ; for since the weight of the body 
 P is always the same, and since its proportion to that part 
 which urges it down the plane is the same, it follows that 
 the quantity of this part cannot vary. The motion of a heavy 
 body down an inclined plane is therefore an uniformly accel- 
 erated motion, and is characterized by all the properties of 
 uniformly accelerated motion, explained in the last chapter. 
 
 Since P F represents the force of gravity, that is, the force 
 with which the body would descend freely in the vertical 
 direction, and P C the force with which it moves down the 
 plane, it follows that a body would fall freely in the vertical 
 direction from P to F in the same time as on the plane it 
 would move from P to C. In this manner, therefore, when 
 the height through which a body would fall vertically is known, 
 the space through which it would descend in the same time 
 down any given inclined plane may be immediately deter- 
 mined. For let A B, Jig. 25., be the given inclined plane, 
 and let P F be the space through which the body would fall 
 in one second. From F draw F C perpendicular to the plane, 
 and the space P C is that through which the body P will fall 
 in one second on the plane. 
 
 (133.) As the angle BAH, which measures the elevation 
 of the plane, is increased, the obliquity of the vertical direc- 
 tion P F with the plane is also increased. Consequently, 
 according to what has been proved (130), it follows, that, as 
 the elevation of the plane is increased, the force which urges 
 the body down tho plane is also increased, and as the eleva- 
 tion is diminished, the force suffers a corresponding diminu- 
 tion. The two extreme cases are, 1. When the plane is 
 raised until it becomes perpendicular, in which case the 
 weight is permitted to fall freely, without exerting any pres- 
 sure upon the plane ; and, 2. When the plane is depressed 
 until it becomes horizontal, in which case the whole weight 
 is supported, and there is no motion. 
 
__ I 
 
 82 THE ELEMENTS OF MECHANICS. CHAP. VIII. 
 
 From these circumstances it follows, that, by means of an 
 inclined plane, we can obtain an uniformly accelerating force 
 of any magnitude less than that of gravity. 
 
 We have here omitted, and shall for the present in every 
 instance omit, the effects of friction, by which the motion 
 down the plane is retarded. Having first investigated the 
 mechanical properties of bodies supposed to be free from 
 friction, we shall consider friction separately, and show how 
 the present results are modified by it. 
 
 (134.) The accelerating forces on different inclined planes 
 may be compared by the principle explained in (131). Let 
 Jigs. 25. and 26. be two inclined planes, and take the lines 
 P F in each figure equal, both expressing the force of gravity, 
 then P C will be the force which in each case urges the body 
 down the plane. 
 
 As the force down an inclined plane is less than that 
 which urges a body falling freely in the vertical direction, 
 the space through which the body must fall to attain a certain 
 final velocity must be just so much greater as the acceler- 
 ating force is less. On this principle we shall be able to de- 
 termine the final velocity in descending through any space 
 on a plane, compared with the final velocity attained in fall- 
 ing freely in the vertical direction. Suppose the body P, 
 Jig. 27., placed at the top of the plane, and from H draw 
 the perpendicular H C. If B H represent the force of grav- 
 ity, B C will represent the force down the plane (131). In 
 order that the body moving down the plane shall have a final 
 velocity equal to that of one which has fallen freely from 
 B to H, it will be necessary that it should move from B down 
 the plane, through a space which bears the same proportion 
 to B H as B H does to B C. But since the triangle A B H 
 is in all respects similar to H B C, only made upon a larger 
 scale, the line A B bears the same proportion to B H as B H 
 bears to B C. Hence, in falling on the inclined plane from 
 B to A, the final velocity is the same as in falling freely from 
 BtoH. 
 
 It is evident that the same will be true at whatever level 
 an horizontal line be drawn. Thus, if I K be horizontal, 
 the final velocity in falling on the plane from B to I will 
 be the same as the final velocity in falling freely from B 
 toK. 
 
 (135.) The motion of a heavy body down a curve differs in 
 an important respect from the motion down an inclined plane. 
 
i 
 
 t 
 
 CHAP. VIII. CENTRIFUGAL FORCE. 83 
 
 Every part of the plane being equally inclined to the verti- 
 cal direction, the effect of gravity in the direction of the 
 plane is uniform ; and, consequently, the phenomena obey all 
 the established laws of uniformly accelerated motion. If, 
 however, we suppose the line B A, on which the body P 
 descends, to be curved, as in Jig. 28, the obliquity of its di- 
 rection at different parts, to the direction P F of gravity, 
 will evidently vary. In the present instance, this obliquity 
 is greater towards B and less towards A, and hence the 
 part of the force of gravity which gives motion to the body is 
 greater towards B than towards A (130). The force, there- 
 fore, which urges the body, instead of being uniform, as in 
 the inclined plane, is here gradually diminished. The rate 
 of this diminution depends entirely on the nature of the curve, 
 and can be deduced from the properties of the curve by 
 mathematical reasoning. The details of such an investiga- 
 tion are not, however, of a sufficiently elementary character 
 to allow of being introduced with advantage into this treatise. 
 We must therefore limit ourselves to explain such of the re- 
 sults as may be necessary for the developement of the other 
 parts of the science. 
 
 (136.) When a heavy body is moved down an inclined 
 plane by the force of gravity, the plane has been proved to 
 sustain a pressure, arising from a certain part of the weight 
 P T),Jig. 25., which acts perpendicularly to the plane. This 
 is also the case in moving down a curve such as B A, Jig. 28. 
 In this case, also, the whole weight is distributed between that 
 part which is directed down the curve, and that which, being 
 perpendicular to the curve, produces a pressure upon it. 
 There is, however, another cause which produces a pressure 
 upon the curve, and which has no operation in the case of 
 the inclined plane. By the property of inertia, when a body 
 is put in motion in any direction, it must persevere in that 
 direction, unless it be deflected from it by an efficient force. 
 In the motion down an inclined plane, the direction is never 
 changed, and therefore, by its inertia, the falling body retains 
 all the motion impressed upon it continually in the same 
 direction ; but when it descends upon a curve, its direction 
 is constantly varying, and the resistance of the curve being 
 the deflecting cause, the curve must sustain a pressure equal 
 to that force which would thus be capable of continually de- 
 flecting the body from the rectilinear path in which it would 
 move in virtue of its inertia. This pressure entirely depends 
 
84 THE ELEMENTS OF MECHANICS. CHAP. VIII 
 
 on the curvature of the path in which the body is constrain- 
 ed to move, and on its inertia, and is therefore altogether in- 
 dependent of the weight, and would, in fact, exist if the weight 
 were without effect. 
 
 (137.) This pressure has been denominated centrifugal 
 force, because it evinces a tendency of the moving body to 
 fly from the centre of the curve in which it is moved. Its 
 quantity depends conjointly on the velocity of the motion and 
 the curvature of the path through which the body is moved. 
 As circles may be described with every degree of curvature, 
 according to the length of the radius, or the distance from 
 their circumference to their centre, it follows that, whatever 
 be the curve in which the body moves, a circle can always be 
 assigned which has the same curvature as is found at any 
 proposed point of the given curve. Such a circle is called 
 "the circle of curvature" at that point of the curve ; and as 
 all curves, except the circle, vary their degrees of curvature 
 at different points, it follows that different parts of the same 
 curve will have different circles of curvature. It is evident 
 that the greater the radius of a circle is, the less is its curvature : 
 thus the circle with the radius A B, Jig. 29., is more curved 
 than that whose radius is C D, and that in the exact proportion 
 of the radius C D to the radius A B. The radius of the circle 
 of curvature for any part of a curve is called " the radius of 
 curvature" of that part. 
 
 (13^.) The centrifugal pressure increases as the radius of 
 curvature increases; but it also has a dependence on the 
 velocity with which the moving body swings round the centre 
 of the circle of curvature. This velocity is estimated either 
 by the actual space through which the body moves, or by the 
 angular velocity of a line drawn from the centre of the circle 
 to the moving body. That body carries one end of this 
 line with it, while the other remains fixed at the centre. As 
 this angular swing round the centre increases, the centrifugal 
 pressure increases. To estimate the rate at which this pres- 
 sure in general varies, it is necessary to multiply the square 
 of the number expressing the angular velocity by that which 
 expresses the radius of curvature, and the force increases in 
 the same proportion as the product thus obtained. 
 
 (139.) We have observed that the same causes which pro- 
 duce pressure on a body restrained, will produce motion if the 
 body be free. Accordingly, if a body be moved by any efficient 
 cause in a curve, it will, by reason of the centrifugal force, 
 
CHAP. VIII. CENTRIFUGAL FORCE. 85 
 
 fly off, and the moving force with which it will thus retreat 
 from the centre round which it is whirled, will be a measure 
 of the centrifugal force. Upon this principle an apparatus 
 called a whirling table has been constructed, for the purpose 
 of exhibiting experimental illustrations of the laws of centrif- 
 ugal force. By this machine we are enabled to place any 
 proposed weights at any given distances from centres round 
 which they are whirled, either with the same angular velocity, 
 or with velocities having a certain proportion. Threads at- 
 tached to the whirling weights are carried to the centres round 
 which they respectively revolve, and there, passing over pul- 
 leys, are connected with weights which may be varied at 
 pleasure. When the whirling weights ily from their respec- 
 tive centres, by reason of the centrifugal force, they draw up 
 the weights attached to the other ends of the threads, and the 
 amount of the centrifugal force is estimated by the weight 
 which it is capable of raising. 
 
 With this instrument the following experiments may be 
 exhibited : 
 
 Exp. 1. Equal weights whirled with the same velocity at 
 equal distances from the centre raise the same weight, and 
 therefore have the same centrifugal force. 
 
 Exp. 2. Equal weights whirled with the same angular 
 velocity at distances from the centre in the proportion of one 
 to two, will raise weights in the same proportion. Therefore 
 the centrifugal forces are in that proportion. 
 
 Exp. 3. Equal weights whirled at equal distances with 
 angular velocities which are as one to two, will raise weights 
 as one to four ; that is, as the squares of the angular velocities. 
 Therefore the centrifugal forces are in that proportion. 
 
 Exp. 4. Equal weights whirled at distances which are as 
 two to three, with angular velocities which are as one to two, 
 will raise weights which are as two to twelve ; that is, as the 
 products of the distances two and three, and the squares, one 
 and four, of the angular velocities. Hence the centrifugal 
 forces are in this proportion. 
 
 The centrifugal force must also increase as the mass of the 
 body moved increases ; for, like attraction, each particle of the 
 moving body is separately and equally affected by it. Hence 
 a double mass, moving at the same distance, and with the 
 same velocity, will have a double force. The following ex- 
 periment verifies this : 
 
 Exp. 5. If weights, which are as one to two, be whirled at 
 8 
 
86 THE ELEMENTS OF MECHANICS. CHAP. VIII. 
 
 equal distances with the same velocity, they will raise weights 
 which are as one to two. 
 
 (140.) The consideration of centrifugal force proves that 
 if a body be observed to move in a curvilinear path, some 
 efficient cause must exist which prevents it from flying off, 
 and which compels it to revolve round the centre. If the body 
 be connected with the centre by a thread, cord, or rod, then 
 the effect of the centrifugal force is to give tension to the 
 thread, cord, or rod. If an unyielding curved surface be 
 placed on the convex side of the path, then the force will 
 produce pressure on this surface. But if a body is observed 
 to move in a curve without any visible material connection 
 with its centre, and without any obstruction on the convex 
 side of its path to resist its retreat, as is the case with the 
 motions of the planets round the sun, and the satellites round 
 the planets, it is usual to assign the cause to the attraction of 
 the body which occupies the centre : in the present instance, 
 the sun is that body, and it is customary to say that the at- 
 traction of the sun, neutralizing the effects of the centrifugal 
 force of the planets, retains them in their orbits. We have 
 elsewhere animadverted on the inaccurate and unphilosophi- 
 cal style of this phraseology, in which terms are admitted 
 which intimate not only an unknown cause, but assign its 
 seat, and intimate something of its nature. All that we 
 are entitled to declare in this case is, that a motion is con- 
 tinually impressed upon the planet ; that this motion is direct- 
 ed towards the sun ; that it counteracts the centrifugal force ; 
 but from whence this motion proceeds, whether it be a virtue 
 resident in the sun, or a property of the medium or space 
 in which both sun and planets are placed, or whatever other 
 influence may be its proximate cause, we are altogether ig- 
 norant. 
 
 (141.) Numerous examples of the effects of centrifugal 
 force may be produced. 
 
 If a stone or other weight be placed in a sling, which is 
 whirled round by the hand in a direction perpendicular to the 
 ground, the stone will not fall out of the sling, even when it 
 is at the top of its circuit, and, consequently, has no support 
 beneath it. The centrifugal force, in this case, acting from 
 the hand, which is the centre of rotation, is greater than the 
 weight of the body, and therefore prevents its fall. 
 
 In like manner, a glass of water may be whirled so rapidly, 
 that, even when the mouth of the glass is presented down- 
 

 CHAP. VIII. FAMILIAR EXAMPLES. 87 
 
 wards, the water will still be retained in it by the centrifugal 
 force. 
 
 If a bucket of water be suspended by a number of threads, 
 and these threads be twisted by turning round the bucket 
 many times in the same direction, on allowing the cords to 
 untwist, the bucket will be whirled rapidly round, and the 
 water will be observed to rise on its sides and sink at its 
 centre, owing to the centrifugal force with which it is driven 
 from the centre. This effect might be carried so far, that 
 all the water would flow over, and leave the bucket nearly 
 empty. 
 
 (142.) A carriage, or horseman, or pedestrian, passing a 
 corner, moves in a curve, and suffers a centrifugal force, which 
 increases with the velocity, and v/hich impresses on the body 
 a force directed from the corner. An animal causes its weight 
 to resist this force, by voluntarily inclining its body towards 
 the corner. In this case, let A B,Jig. 30., be the body ; C D 
 is the direction of the weight perpendicular to the ground, 
 and C F is the direction of the centrifugal -force parallel to 
 the ground and from the corner. The body A B is inclined 
 to the corner, so that the diagonal force (74), which is me- 
 chanically equivalent to the weight and centrifugal force, shall 
 be in tie direction C A, and shall therefore produce the pres- 
 sure of the feet upon the ground. 
 
 As the velocity is increased, the centrifugal force is also 
 increased, and therefore a greater inclination of the body is 
 necessary to resist it. We accordingly find that the more 
 rapidly a corner is turned, the more the animal inclines his 
 body towards it. 
 
 A carriage, however, not having voluntary motion, cannot 
 make this compensation for the disturbing force which is call- 
 ed into existence by the gradual change of direction of the 
 motion; consequently it will, under certain circumstances, be 
 overturned, falling, of course, outwards, or from the corner. If 
 A B be the carriage, and C, jig 31., the place at which the 
 weight is principally collected, this point C will be under the 
 influence of two forces; the weight, which may be represent- 
 ed by the perpendicular C D, and the centrifugal force, which 
 will be represented by a line C F, which shall have the same 
 proportion to C D as the centrifugal force has to the weight. 
 Now the combined effect of these two forces will be the same 
 as the effect of a single foi ce, represented by C G. Thus 
 the pressure of the carriage on the road is brought nearer te 
 
88 THE ELEMENTS OF MECHANICS. CHAP. VIII. 
 
 the outer wheel B. If the centrifugal force bear the same 
 proportion to the weight as C F (or D B),Jig. 32., bears to 
 C D, the whole pressure is thrown upon the wheel B. 
 
 If the centrifugal force bear to the weight a greater pro- 
 portion than D B has to C D, then the line C F, which repre- 
 sents it, Jig. 33., will be greater than D B. The diagonal 
 C G, which represents the combined effects of the weight and 
 centrifugal force, will in this case pass outside the wheel B, 
 and therefore this resultant will be unresisted. To perceive 
 how far it will tend to overturn the carriage, let the force C G 
 be resolved into two, one in the direction of C B, and the 
 other C K, perpendicular to C B. The former C B will be 
 resisted by the road, but the latter C K will tend to lift the 
 carriage over the external wheel. If the velocity and the 
 curvature of the course be continued for a sufficient time to 
 enable this force C K to elevate the weight, so that the line of 
 direction shall fall on B, the carriage will be overthrown. 
 
 It is evident from what has been now stated, that the 
 chances of overthrow under these circumstances depend on 
 the proportion of B D to C D, or, what is to the same purpose, 
 of the distance between the wheels to the height of the prin- 
 cipal seat of the load. It will be shown in the next chapter, 
 that there is a certain point, called the centre of gravity, at 
 which the entire weight of the vehicle and its load may be 
 conceived to be concentrated. This is the point which in the 
 present investigation we have marked C. The security of 
 the carriage, therefore, depends on the greatness of the dis- 
 tance between the wheels, and the smallncss of the elevation 
 of the centre of gravity above the road ; for either or both of 
 these circumstances will increase the proportion of B D to C D. 
 
 (143.) In the equestrian feat exhibited in the ring at the 
 amphitheatre, when the horse moves round with the performer 
 standing on the saddle, both the horse and rider incline con- 
 tinually towards the centre of the ring, and the inclination 
 increases with the velocity of the motion : by this inclination 
 their weights counteract the effect of the centrifugal force, 
 exactly as in the case already mentioned (142). 
 
 (144.) If a body be allowed to fall by its weight down a 
 convex surface, such as A B,.fiff. 34., it would continue upon 
 the surface until it arrive at B, but for the effect of the cen- 
 trifugal force : this, giving it a motion from the centre of the 
 curve, will cause it to quit the curve at a certain point C, 
 M liich can be easily found by mathematical computation. 
 

 CHAP. VIII. FAMILIAR EXAMPLES. 
 
 (145.) The most remarkable and important manifestation 
 of centrifugal force is observed in the effects produced by 
 the rotation of the earth upon its axis. Let the circle in 
 Jig. 35. represent a section of the earth, A B being the axis 
 on which it revolves. This rotation causes the matter which 
 composes the mass of the earth, to revolve in circles round 
 the different points of the axis as centres at the various dis- 
 tances at which the component parts of this mass are placed. 
 As they all revolve with the same angular velocity, they will 
 be affected by centrifugal forces, which will be greater or less 
 in proportion as their distances from the centre are greater 
 or less. Consequently the parts of the earth which are 
 situated about the equator, D, will be more strongly af- 
 fected by centrifugal force than those about the poles, A B. 
 The effect of this difference has been that the component 
 matter about the equator has actually been driven farther 
 from the centre than that about the poles, so that the figure 
 of the earth has swelled out at the sides, and appears propor- 
 tionally depressed at the top and bottom, resembling the 
 shape of an orange. An exaggerated representation of this 
 figure is given in Jig. 36. ; the real difference between the 
 distances of the poles and equator from the centre being too 
 small to be perceptible in a diagram. The exact proportion 
 of C A to C D has never yet been certainly ascertained. 
 Some observations make C D exceed C A by ^ T , and 
 others by only ^^-. The latter, however, seems the more 
 probable. It may be considered to be included between 
 these limits. 
 
 The same cause operates more powerfully in other plan- 
 ets which revolve more rapidly on their axes. Jupiter and 
 Saturn have forms which are considerably more elliptical. 
 
 (14G.) The centrifugal force of the earth's rotation also 
 affects detached bodies on its surface. If such bodies were 
 not held upon the surface by the earth's attraction, they 
 would be immediately flung off by the whirling motion in 
 which they participate. The centrifugal force, however, 
 really diminishes the effects of the earth's attraction on those 
 bodies, or, what is the same, diminishes their weights. If 
 the earth were not revolving on its axis, the weight of bodies 
 in all places equally distant from the centre would be the 
 same ; but this is not so when the bodies, as they do, move 
 round with the earth. They acquire from the centrifugal 
 force a tendency to fly from the axis, which increases with 
 8* 
 
90 THE ELEMENTS OF MECHANICS. CHAP. IX. 
 
 their distance from that axis, and is, therefore, greater the 
 nearer they are to the equator, and less as they approach 
 the pole. But there is another reason why the centrifugal 
 force is more efficient in the opposition which it gives to 
 gravity near the equator than near the poles. This force 
 does not act from the centre of the earth, hut is directed 
 from the earth's axis. It is, therefore, not directly opposed 
 to gravity, except on the equator itself. On leaving the 
 equator, and proceeding towards the poles, it is less and less 
 opposed to gravity, as will be plain on inspecting Jig. 35., 
 where the lines P C all represent the direction of gravity, 
 and the lines P F represent the direction of the centrifugal 
 force. 
 
 Since, then, as we proceed from the equator towards the 
 poles, not only the amount of the centrifugal force is con- 
 tinually diminished, but also it acts less and less in opposition 
 to gravity, it follows that the weights of bodies are most 
 diminished by it at the equator, and less so towards the poles. 
 
 Since bodies are commonly weighed by balancing them 
 against other bodies of known weight, it may be asked, how 
 the phenomena we have been just describing can be ascer- 
 tained as a matter of fact; for whatever be the body against 
 which it may be balanced, that body must suffer just as much 
 diminution of weight as every other, and, consequently, -all 
 being diminished in the same proportion, the balance will 
 be preserved tliough the weights be changed. 
 
 To render this effect observable, it will be necessary to 
 compare the effects of gravity with some phenomenon which 
 is not affected by the centrifugal force of the earth's rotation, 
 and which will be the same at every part of the earth. The 
 means of accomplishing this will be explained in a subse- 
 quent chapter. 
 
 CHAPTER IX. 
 
 THE CENTRE OF GRAVITY. 
 
 (147.) BY the earth's attraction, all the particles which 
 compose the mass of a body are solicited by equal forces in 
 parallel directions downwards. If these component particles 
 were placed in mere juxtaposition, without any mechanical 
 
CHAP. IX. CENTRE OF GRAVITY. 91 
 
 connection, the force impressed on any one of them could 
 in nowise affect the others, and the mass would, in such a 
 case, be contemplated as an aggregation of small particles of 
 matter, each urged by an independent force. But the bodies 
 which are the subjects of investigation in mechanical sci- 
 ence are not found in this state. Solid bodies are coherent 
 masses, the particles of which are firmly bound together, so 
 that any force which affects one, being modified according to 
 circumstances, will be transmitted through the whole body. 
 Liquids accommodate themselves to the shape of the surfaces 
 on which they rest, and forces affecting any one part are 
 transmitted to others, in a manner depending on the peculiar 
 properties of this class of bodies. 
 
 As all bodies, which are subjects of mechanical inquiry, 
 on the surface of the earth, must be continually influenced 
 by terrestrial gravity, it is desirable to obtain some easy and 
 summary method of estimating the effect of this force. To 
 consider it, as is unavoidable in the first instance, the com- 
 bined action of an infinite number of equal and parallel 
 forces soliciting the elementary molecules downwards, would 
 be attended with manifest inconvenience. An infinite num- 
 ber of forces, and an infinite subdivision of the mass, would 
 form parts of every mechanical problem. 
 
 To overcome this difficulty; and to obtain all the ease and 
 simplicity which can be desired in elementary investigations, 
 it is only necessary to determine some force, whose single 
 effect shall be equivalent to the combined effects of the grav- 
 itation of all the molecules of the body. If this can be 
 accomplished, that single force might be introduced into all 
 problems to represent the whole effect of the earth's attrac- 
 tion, and no regard need be had to any particles of the 
 body, except that on which this force acts. 
 
 (148.) To discover such a force, if it exist, we shall first 
 inouire what properties must necessarily characterize it. Let 
 A B,Jig. 37., be a solid body placed near the surface of the 
 earth. Its particles are all solicited downwards, in the direc- 
 tions represented by the Tirrows. Now, if there be any single 
 force equivalent to these combined effects, two properties 
 maybe at once assigned to it: 1. It must be presented 
 downwards, in the common direction of those forces to which 
 it is mechanically equivalent ; and, 2." it must be equal in 
 intensity to their sum, or, what is the same, to the force with 
 which the whole mass would descend. We shall then sup- 
 
92 THE ELEMENTS OF MECHANICS. CHAP. IX. 
 
 pose it to have this intensity, and to have the direction of the 
 arrow D E. Now, if the single force, in the direction D E, 
 be equivalent to all the separate attractions which affect the 
 particles, we may suppose all these attractions removed, and 
 the body A B influenced only by a single attraction, acting 
 in the direction D E. This being admitted, it follows that if 
 the body be placed upon a prop, immediately under the direc- 
 tion of the line D E, or be suspended from a fixed point 
 immediately above its direction, it will remain motionless. 
 For the whole attracting force in the direction D E will, in 
 the one case, press the body on the prop, and, in the other 
 case, will give tension to the cord, rod, or whatever other 
 means of suspension be used. 
 
 (149.) But suppose the body were suspended from some 
 point P, not in the direction of the line D E. Let P C be 
 the direction of the thread by which the body is suspended. 
 Its whole weight, according to the supposition which we have 
 adopted, must then act in the direction C E. Taking C F 
 to represent the weight, it may be considered as mechani- 
 cally equivalent to two forces (74), C I and C H. Of these, 
 C II, acting directly from the point P, merely produces pres- 
 sure upon it, and gives tension to the cord P C; but C I, 
 acting at right angles to C P, produces motion round P as 
 a centre, and in the direction C 1, towards a vertical line 
 P G, drawn through the point P. If the body A B had 
 been on the other side of .the line P G, it \.ould have moved, 
 in like manner, towards it, and, therefore, in the direction 
 contrary to its present motion. 
 
 Hence we must infer, that, when the body is suspended 
 from a fixed point, it cannot remain at rest, if that fixed 
 point be not placed in the direction of the line D E; and, 
 on the other hand, that if the fixed point be in the direction 
 of that line, ite cannot move. A practical test is thus sug- 
 gested, by which the line D E may be at once discovered. 
 Let a thread be attached to any point of the body, and let it 
 be suspended by this thread from a hook or other fixed point. 
 The direction of the thread, when the body becomes quies- 
 cent, will be that of a single force equivalent to the gravita- 
 tion of all the component parts of the mass. 
 
 (150.) An inquiry is here suggested : Does the direction 
 of the equivalent force, thus determined, depend on the 
 position of the body with respect to the surface of the earth, 
 and how is the direction of the equivalent force affected by a 
 
i 
 
 CHAP. I*. CENTRE OF GRAVITY. 93 
 
 change in that position? This question may be at once 
 solved if the body be suspended by different points, and the 
 directions which the suspending thread takes in each case 
 relatively to the figure and dimensions of the body ex- 
 amined. 
 
 The body being suspended in this manner from any point, 
 let a small hole be bored through it, in the exact direction of 
 the thread, so that, if the thread were continued below th 
 point where it is attached to the body, it would pass throug 
 this hole. The body being successively suspended by severa. 
 different points on its surface, let as many small holes be 
 bored through it in the same manner. If the body be then 
 cut through, so as to discover the directions which the several 
 holes have taken, they will be all found to cross each other 
 at one point within the body ; or the same fact may be dis- 
 covered thus : a thin wire, which nearly fills the holes, being 
 passed through any one of them, it will be found to intercept 
 the passage of a similar wir,; through any other. 
 
 This singular fact teaches us, what, indeed, can be proved 
 by mathematical reasoning without experiment, that there is 
 one point in every body through which the single force, which 
 is equivalent to the gravitation of all its particles, must pass 
 in whatever position the body be placed. This point is called 
 the centre of gravity. 
 
 (151.) In whatever situation a body may be placed, the 
 centre of gravity will have a tendency to descend in the di- 
 rection of a line perpendicular to the horizon, and which is 
 called the line of direction of the weight. If the body be 
 altogether free and unrestricted by any resistance or impedi- 
 ment, the centre of gravity will actually descend in this di- 
 rection, and all the other points of the body will move with 
 the same velocity in parallel directions, so that, during its fall, 
 the position of the parts of the body, with respect to the 
 ground, will be unaltered. But if the body, as is most usual, 
 be subject to some resistance or restraint, it will either remain 
 unmoved, its weight being expended in exciting pressure on 
 the restraining points or surfaces, or it will move in a direc- 
 tion and with a velocity depending on the circumstances 
 which restrain it. 
 
 In order to determine those effects, to predict the pressure 
 produced by the weight, if the body be quiescent, or the 
 mixed effects of motion and pressure, if it be not so, it is 
 necessary in all cases to be able to assign the place of the 
 
94 THE ELEMENTS OF MECHANICS. CHAP. IX. 
 
 centre of gravity. When the magnitude and figure of the 
 body, and the density of the matter which occupies its di- 
 mensions, are known, the place of the centre of gravity can 
 be determined with the greatest precision by mathematical 
 calculation. The process by which this is accomplished, 
 however, is not of a sufficiently elementary nature to be 
 properly introduced into this treatise. To render it intelligi- 
 ble would require the aid of some of the most advanced 
 analytical principles ; and even to express the position of the 
 point in question, except in very particular instances, would 
 be impossible, without the aid of peculiar symbols. 
 
 (152.) There are certain particular forms of body in which, 
 when they are uniformly dense, the place of the centre of 
 gravity can be easily assigned, and proved by reasoning 
 which is generally intelligible ; but in all cases whatever, 
 this point may be easily determined by experiment. 
 
 (153.) If a body uniformly dense have such a shape that a 
 point may be found, on either side of which, in all directions 
 around it, the materials of the body are similarly distributed, 
 that point will obviously be the centre of gravity. For if it 
 be supported, the gravitation of the particles on one side 
 drawing them downwards, is resisted by an effect of exactly 
 the same kind and of equal amount on the opposite side, and 
 so the body remains balanced on the point. 
 
 The most remarkable body of this kind is a globe, the 
 centre of which is evidently its centre of gravity. 
 
 A figure, such as Jig. 38., called an oblate spheroid, has 
 its centre of gravity at its centre, C. Such is the figure of 
 the earth. The same may be observed of the elliptical solid, 
 jig. 39., which is called a prolate spheroid. . 
 
 A cube, and some other regular solids, bounded by plane 
 surfaces, have a point within them, such as above described, 
 and which is, therefore, their centre of gravity. Such are 
 Jig. 40. 
 
 A straight wand, of uniform thickness, has its centre of 
 gravity at the centre of its length ; and a cylindrical body 
 has its centre of gravity in its centre, at the middle of its 
 length or axis. Such is the point C, Jig. 41. 
 
 A flat plate of any uniform substance, and which has, in 
 every part, an equal thickness, has its centre of gravity at 
 the middle of its thickness, and under a point of its surface, 
 which is to be determined by its shape. If it be circular or 
 elliptical, this point is its centre. If it have any regular 
 
CHAP. IX. CENTRE OF GRAVITY, 95 
 
 form, bounded by straight edges, it is that point which is 
 equally distant from its several angles, as C in Jig. 42. 
 
 (154.) There are some cases in which, although the place 
 of the centre of gravity is not so obvious as in the examples 
 j'ust given, still it may be discovered, without any mathemat- 
 ical process, which is not easily understood. Suppose ABC, 
 Jig. 43., to be a flat triangular plate of uniform thickness 
 and density. Let it be imagined to be divided into narrow 
 bars, by lines parallel to the side A C, as represented in the 
 figure. Draw B D from the angle B to the middle point D 
 ef the side A C. It is not difficult to perceive, that B D 
 will divide equally all the bars into which the triangle is con- 
 ceived to be divided. Now, if the flat triangular plate ABC 
 be placed in a horizontal position on a straight edge coincid- 
 ing with the line B D, it will be balanced ; for the bars 
 parallel to A C will be severally balanced by the edge imme- 
 diately under their middle point, since that middle point is 
 the centre of gravity of each bar. Since, then, the triangle 
 is balanced on the edge, the centre of gravity must be some- 
 where immediately over it, and must, therefore, be within 
 the plate, at some point under the line B D. 
 
 The same reasoning will prove that the centre of gravity 
 of the plate is under the line A E, drawn from the angle A 
 to the middle point E of the side B C. To perceive this, it 
 is only necessary to consider the triangle divided into bars 
 parallel to B C, and thence to show that it will be balanced 
 on an edge placed under A E. Since, then, the centre of 
 gravity of the plate is under the line B D, and also under 
 A E, it must be under the point G, at which these lines cross 
 each other; and it is accordingly at a depth beneath G, 
 equal to half the thickness of the plate. 
 
 This may be experimentally verified by taking a piece of 
 tin or card, and cutting it into a triangular form. The point 
 G being found by drawing B D and A E, which divide two 
 sides equally, it will be balanced if placed upon the point of 
 a pin at G. 
 
 The centre of gravity of a triangle being thus determined, 
 we shall be able to find the position of the centre of gravity 
 of any plate of uniform thickness and density which is 
 bounded by straight edges, as will be shown hereafter (173). 
 
 (155.) The centre of gravity is not always included within 
 the volume of the body, that is, it is not enclosed by its sur- 
 faces. Numerous examples of this can be produced. If a 
 
 
96 THE ELEMENTS OF MECHANICS. CHAP. IX 
 
 piece of wire be bent into any form, the centre of gravity 
 will rarely be in the wire. Suppose it be brought to the 
 form of a ring. In that case, the centre of gravity of the 
 wire will be the centre of the circle, a point not forming any 
 part of the wire itself: nevertheless this point may be proved 
 to have the characteristic property of the centre of gravity ; 
 for if the ring be suspended by any point, the centre of the 
 ring must always settle itself under the point of suspension. 
 If this centre could be supposed to be connected with the 
 ring by very fine threads, whose weight would be insignifi- 
 cant, and which might be united by a knot or otherwise at 
 the centre, the ring would be balanced upon a point placed 
 under the knot. 
 
 In like manner, if the wire be formed into an ellipse, or 
 any other curve similarly arranged round a centre point, that 
 point will be its centre of gravity. 
 
 (156.) To find the centre of gravity experimentally, the 
 method described in (149, 150) may be used. In this case 
 two points of suspension will be sufficient to determine it ; 
 for the directions of the suspending cord, being continued 
 through the body, will cross each other at the centre of grav- 
 ity. These directions may also be found by placing the 
 body on a sharp point, and adjusting it so as to be balanced 
 upon it. In this case, a line drawn through the body directly 
 upwards from the point will pass through the centre of grav- 
 ity, and, therefore, two such lines must cross at that point. 
 
 (157.) If the body have two flat parallel surfaces, like 
 sheet metal, stiff paper, card, board, &c., the centre of grav- 
 ity may be found by balancing the body in two positions on 
 an horizontal straight edge. The point where the lines 
 marked by the edge cross each other will be immediately 
 under the centre of gravity. This may be verified by show- 
 ing that the body will be balanced on a point thus placed, or 
 that, if it be suspended, the point thus determined will always 
 come under the point of suspension. 
 
 The position of the centre of gravity of such bodies may 
 also be found by placing the body on an horizontal table 
 having a straight edge. The body being moved beyond the 
 edge until it is in that position in which the slightest distur- 
 bance will cause it to fall, the centre of gravity will then 
 be immediately over the edge. This being done in two 
 positions, the centre of gravity will be determined as before. 
 
 (158.) It has been already stated, that when the body is 
 
U1AP. IX. CENTRE OP GRAVITY. 97 
 
 perfectly free, the centre of gravity must necessarily move 
 downwards, in a direction perpendicular to an horizontal 
 plane. When the body is not free, the circumstances which 
 restrain it generally permit the centre of gravity to move in 
 certain directions, but obstruct its motion in others. Thus, 
 if a body be suspended from a fixed point by a flexible cord, 
 the centre of gravity is free to move in every direction except 
 those which would carry it farther from the point of suspen- 
 sion than the length of the cord. Hence if we conceive a 
 globe or sphere to surround the point of suspension on every 
 side to a distance equal to that of the centre of gravity from 
 the point of suspension, when the cord is fully stretched, the 
 centre of gravity will be at liberty to move in every direction 
 within this sphere. 
 
 There are an infinite variety of circumstances under 
 which the motion of a body may be restrained, and in 
 which a most important and useful class of mechanical prob- 
 lems originate. Before we notice others, we shall, however, 
 examine that which has just been described more particularly. 
 
 Let P, jig. 44., be the point of suspension, and C the 
 centre of gravity, and suppose the body so placed that C 
 shall be within the sphere already described. The cord will 
 therefore be slackened, and in this state the body will be 
 free. The centre of gravity will therefore descend in the 
 perpendicular direction until the cord becomes fully extend- 
 ed ; the tension will then prevent its further motion in the 
 perpendicular direction. The downward force must now be 
 considered as the diagonal of a parallelogram, and equivalent 
 to two forces C D and C E, in the directions of the sides, as 
 already explained in (149). The force C D will bring the 
 centre of gravity into the direction P F, perpendicularly 
 under the point of suspension. Since the force of gravity 
 acts continually on C in its approach to P F, it will move 
 towards that line with accelerated speed, and when it has 
 arrived there, it will have acquired a force to which no ob- 
 struction is immediately opposed, and, consequently, by its 
 inertia, it retains this force, and moves beyond P F on the 
 other side. But when the point C gets into the line P F, it 
 is in the lowest possible position ; for it is at the lowest point 
 of the sphere which limits its motion. When it passes to 
 the other side of P F, it must therefore begin to ascend, and 
 the force of gravity, which, in the former case, accelerated 
 its descent, will now, for the same reason, and with equal 
 9 
 
98 THE ELEMENTS OF MECHANICS. CHAP. IX. 
 
 energy, oppose its ascent. This will be easily understood. 
 Let C' be any point which it may have attained in ascending ; 
 C' G', the force of gravity, is now equivalent to C' D' 
 and C' E'. The latter, as before, produces tension ; but the 
 former C' D' is in a direction immediately opposed to the 
 motion, and therefore retards it. This retardation will con- 
 tinue until all the motion acquired by the body in its descent 
 from the first position has been destroyed, and then it will 
 begin to return to P F, and so it will continue to vibrate 
 from the one side to the other until the friction on the point 
 P, and the resistance of the air, gradually deprive it of its 
 motion, and bring it to a state of rest in the direction P F. 
 
 But for the effects of friction and atmospheric resistance, 
 the body would continue for ever to oscillate equally from 
 side to side of the line P F. 
 
 (159.) The phenomenon just developed, is only an example 
 of an extensive class, Whenever the circumstances which 
 restrain the body are of such a nature that the centre of 
 gravity is prevented from descending below a certain level, 
 but not, on the other hand, restrained from rising above it, 
 the body will remain at rest if the centre of gravity be placed 
 at the lowest limit of its level ; any disturbance will cause it 
 to oscillate around this state, and it cannot return to a state 
 of rest until friction or some other cause have deprived it of 
 the motion communicated by the disturbing force. 
 
 (160.) Under the circumstances which we have just de- 
 scribed, the body could not maintain itself in a state of rest 
 in any position except that in which the centre of gravity is, 
 at the lowest point of the space in which it is free to move. 
 This, however, is not always the case. Suppose it were sus- 
 pended by an inflexible rod instead ^of a flexible string; the 
 centre of gravity would then not only be prevented from 
 receding from the point of suspension, but also from ap- 
 proaching it ; in fact, it would be always kept at the same 
 distance from it. Thus, instead of being capable of moving 
 any where within the sphere, it is now capable of moving on 
 its surface only. The reasoning used in the last case may 
 also be applied here, to prove that when the centre of gravity 
 is on either side of the perpendicular P F, it will fall towards 
 P F, and oscillate, and that, if it be placed in the line P F, it 
 will remain in equilibrium. But in this case there is another 
 position, in which the centre of gravity may be placed so as 
 to produce equilibrium. If it be placed at the highest point 
 
CHAP. IX. StABLE AND INSTAOLE EgtJlLiimiUM. 99 
 
 of the sphere in which it moves, the whole force acting on it 
 will then be directed on the point of suspension, perpendicu- 
 larly downwards, and will be entirely expended in producing 
 pressure on that point ; consequently, the body will in this 
 case be in equilibrium. But this state of equilibrium is of a 
 character very different from that in which the centre of grav- 
 ity was at the lowest part of the sphere. In the present case, 
 any displacement, however slight, of the centre of gravity, 
 will carry it to a lower level, and the force of gravity will then 
 prevent its return to its former state, and will impel it down- 
 wards until it attain the lowest point of the sphere, and round 
 that point it will oscillate. 
 
 (161.) The two states of equilibrium which have been just 
 noticed, are called stable and instable equilibrium. The 
 character of the former is, that any disturbance of the state 
 produces oscillation about it; but any disturbance of the lat- 
 ter state produces a total overthrow, and finally causes oscilla- 
 tion around the state of stable equilibrium. 
 
 Let A B,Jig. 45., be an elliptical board resting on its edge 
 on an horizontal "plane. In the position here represented, the 
 extremity P of the lesser axis being the point of support, the 
 board is in stable equilibrium ; for any motion on either side 
 must cause the centre of gravity C to ascend in the directions 
 C O, and oscillation will ensue. If, however, it rest upon the 
 smaller end, as in Jig. 46., the position would still be a state 
 of equilibrium, because the centre of gravity is directly above 
 the point of support ; but it would be instable equilibrium, be- 
 cause the slightest displacement of the centre of gravity would 
 cause it to descend. 
 
 Thus an egg or a lemon may be balanced on the end ; but 
 the least disturbance will overthrow it. On the contrary, it 
 will easily rest on the side, and any disturbance will produce 
 oscillation. 
 
 (162.) When the circumstances under which the body is 
 placed allow the centre of gravity to move only in an horizon- 
 tal line, the body is in a state which may be called neutral 
 equilibrium. The slightest force will move the centre of grav- 
 ity, but will neither produce oscillation nor overthrow the body, 
 as in the last two cases. 
 
 An example of this state is furnished by a cylinder placed 
 upon an horizontal plane. As the cylinder is rolled upon the 
 plane, the centre of gravity G y f,g. 47., moves in a line paral- 
 lel to the plane A B, and distant from it by the radius of the 
 
100 THE ELEMENTS OF MECHANICS. CHAP. IX. 
 
 cylinder. The body will thus rest indifferently in any position, 
 because the line of direction always falls upon a point P at 
 which the body rests upon the plane. 
 
 If the plane were inclined, as in Jig. 48., a body might be 
 so shaped, that, while it would roll, the centre of gravity would 
 move horizontally. In this case, the body would rest indiffer- 
 ently on any part of the plane, as if it were horizontal, pro- 
 vided the friction be sufficient to prevent the body from slid- 
 ing down the plane. 
 
 If the centre of gravity of a cylinder happen not to coincide 
 with its centre, by reason of the want of uniformity in the 
 materials of which it is composed, it will not be in a state of 
 neutral equilibrium on an horizontal plane, as in Jig. 47. In 
 this case, let G, Jig. 49., be the centre of gravity. In the 
 position here represented, where the centre of gravity is im- 
 mediately below the centre C, the state will be stable equilib- 
 rium, because a motion on either side would cause the cen- 
 tre of gravity to ascend; but in Jig. 50., whore G is immedi- 
 ately above C, the state is instable equilibrium, because a 
 motion on either side would cause G to descend, and the body 
 would turn into the position j#,. 49. 
 
 (163.) A cylinder of this kind will, under certain circum- 
 stances, roll up an inclined plane. Let A R,Jig. 51., be the 
 inclined plane, and let the cylinder be so placed that the line 
 of direction from G shall be above the point P at which the 
 cylinder rests upon the plane. The whole weight of the body 
 acting in the direction G D will obviously cause the cylinder 
 to roll towards A, provided the friction be sufficient to prevent 
 sliding ; but although the cylinder in this case ascends, the 
 centre of gravity G really descends. 
 
 When G is so placed that the line of direction G D shall 
 fall on the point P, the cylinder will be in equilibrium, be- 
 cause its weight acts upon the point on which it rests. There 
 are two cases represented in Jig. 52. and Jig. 53., in which G 
 takes this position. Fig. 52. represents the state of stable, 
 and Jig. 53. of instable equilibrium. 
 
 (164.) When a body is placed upon a base, its stability de- 
 pends upon the position of the line of direction and the height 
 of the centre of gravity above the base. If the line of direc- 
 tion fall within the base, the body will stand firm ; if it fall 
 on the edge of the base, it will be in a state in which the slight- 
 est force will overthrow it on that side at which the line of 
 direction falls ; and if the line of direction fall without the 
 
CHAP. IX. STABLE AND INSTABLE EQUILIBRIUM. 101 
 
 base, the body must turn over that edge which is nearest to 
 the line of direction. 
 
 In Jig. 54. and Jig. 55., the line of direction G P falls with- 
 in the base, and it is obyious that the body will stand firm ; 
 for any attempt to turn it over eitker edge would cause the 
 centre of gravity to ascend. But in Jig. 56. the line of direc- 
 tion falls upon the edge, and if the body be turned over, the 
 centre of gravity immediately commences to descend. Until 
 it be turned over, however, the centre of gravity is supported 
 by the edge. 
 
 In jig. 57. the line of direction falls outside the base, the 
 centre of gravity has a tendency to descend from G towards 
 A, and the body will accordingly fall in that direction. 
 
 (165.) When the line of direction falls within the base, bodies 
 will always stand firm, but not with the same degree of stabil- 
 ity. In general, the stability depends on the height through 
 which the centre of gravity must be elevated before the body 
 can be overthrown. The greater this height is, the greater 
 in the same proportion will be the stability. 
 
 Let B A C, Jig. 58., be a pyramid, the centre of gravity 
 being at G. To turn this over the edge B, the centre of 
 gravity must be carried over the arch G E, and must there- 
 fore be raised through the height H E. If, however, the 
 pyramid were taller relatively to its base, as in Jig. 59., the 
 height H E would be proportionally less ; and if the base were 
 very small in reference to the height, as in Jig. 60., the height 
 H E would be very small, and a slight force would throw it 
 over the edge B. 
 
 It is obvious that the same observations may be applied to 
 ill figures whatever, the conclusions just deduced depending 
 only on the distance of the line of direction from the edge of 
 the base, and the height of the centre of gravity above it. 
 
 (166.) Hence we may perceive the principle on which the 
 stability of loaded carriages depends. When the load is placed 
 at a considerable elevation above the wheels, the centre of 
 gravity is elevated, and the carriage becomes proportionally 
 insecure. In coaches for the conveyance of passengers, the 
 luggage is therefore sometimes placed below the body of the 
 coach ; light parcels of large bulk may be placed on the top 
 with impunity. 
 
 When the centre of gravity of a carriage is much elevated, 
 there is considerable danger of overthrow, if a corner be turn- 
 ed sharply and with a rapid pace ; for the centrifugal force 
 9* 
 
102 THE ELEMENTS OF MECHANICS. CHAP. IX. 
 
 then acting on the centre of gravity will easily raise it through 
 the small height which is necessary to turn the carriage over 
 the external wheels (142.). 
 
 (167.) The same wagon will have greater stability when 
 loaded with a heavy substance which occupies a small space, 
 euch as metal, than when it carries the same weight of a light- 
 er substance, such as hay ; because the centre of gravity in 
 the latter case will be much more elevated. 
 
 If a large table be placed upon a single leg in its centre, it 
 will be impracticable to make it stand firm ; but if the pillar 
 on which it rests terminate in a tripod, it will have the same 
 stability as if it had three legs attached to the points directly 
 over the places where the feet of the tripod rest. 
 
 (168.) When a solid body is supported by more points than 
 one, it is not necessary for its stability that the line of direc- 
 tion should fall on one of those points. If there be only two 
 points of support, the line of direction must fall between 
 them. The body is in this case supported as effectually as if 
 it rested on an edge coinciding with a straight line drawn from 
 one point of support to the other. If there be three points of 
 support, which are not ranged in the same straight line, the 
 body will be supported in the same manner as it would be by 
 a base coinciding with the triangle formed by straight lines 
 joining the three points of support. In the same manner, 
 whatever be the number of points on which the body may 
 rest, its virtual base will be found by ;ippo.sing straight lines 
 drawn, joining the several points successively. When the 
 line of direction falls within this base, the body will always 
 stand firm, and otherwise not. The degree of stability is 
 determined in the same manner as if the base were a con- 
 tinued surface. 
 
 (169.) Necessity and experience teach an animal to adapt 
 its postures and motions to the position of the centre of grav- 
 ity of his body. When a man stands, the line of direction of 
 his weight must fall within the base formed by his feet. If 
 A B, C D,Jig. 61., be the feet, this base is the space A B D C. 
 It is evident, that the more his toes are turned outwards, the 
 more contracted the base will be in the direction E F, and 
 the more liable he will be to fall backwards or forwards. Also 
 the closer his feet are together, the more contracted the base 
 will be in the direction G H, and the more liable he will be to 
 fall towards either side. 
 
 When a man walks, the legs are alternately lifted from the 
 
CHAP. IX. FAMILIAR EXAMPLES. 103 
 
 ground, and the centre of gravity is either unsupported or 
 thrown from the one side to the other. The body is also 
 thrown a little forward, in order that the tendency of the cen- 
 tre of gravity to fall in the direction of the toes may assist 
 the muscular action in propelling the body. This forward 
 inclination of the body increases with the speed of the motion. 
 
 But for the flexibility of the knee-joint, the labor of walking 
 would be much greater than it is ; for the centre of gravity 
 would be more elevated by each step. The line of motion of 
 the centre of gravity in walking is represented by Jig. 62., 
 and deviates but little from a regular horizontal line, so that 
 the elevation of the centre of gravity is subject to very slight 
 variation. But if there were no knee-joint, as when a man 
 has wooden legs, the centre of gravity would move as in Jig. 
 (v3., so that at each step the weight of the body would be lift- 
 ed through a considerable height, and therefore the labor of 
 walking would be much increased. 
 
 If a man stand on one leg, the line of direction of his 
 weight must fall within the space on which his foot treads. 
 The smallness of this space, compared with the height of the 
 centre of gravity, accounts ibr the difficulty of this feat. 
 
 The position of the centre of gravity of the body changes 
 with the posture and position of the limbs. If the arm be 
 extended from one side, the centre of gravity is brought near- 
 er to that side than it was when the arm hung perpendicular- 
 ly. When dancers, standing on one leg, extend the other at 
 right angles to it, they must incline the body in the direction 
 opposite to that in which the leg is extended, in order to 
 bring the centre of gravity over the foot which supports 
 them. 
 
 When a porter carries a load, his position must be regulated 
 by the centre of gravity of his body and the load taken to- 
 gether. If he bore the load on his back, the line of direction 
 would pass beyond his heels, and he would fall backwards. 
 To bring the centre of gravity over his feet, he accordingly 
 leans forward,^-. 64. 
 
 If a nurse carry a child in her arms, she leans back for a 
 like reason. 
 
 When a load is carried on the head, the bearer stands up- 
 right, that the centre of gravity may be over his feet. In 
 ascending a hill, we appear to incline forward, and in de- 
 scending, to lean backward ; but in truth we are standing up- 
 right with respect to a level plane. This is necessary to 
 
104 THE ELEMENTS OF MECHANICS. CHAP. IX. 
 
 keep the line of direction between the feet, as is evident from 
 fff. 65. 
 
 A person sitting on a chair which has no back, cannot rise 
 from it without either stooping forward to bring the centre of 
 gravity over the feet, or drawing back the feet to bring them 
 under the centre of gravity. 
 
 A quadruped never raises both feet on the same side simul- 
 taneously, for the centre of gravity would then be unsupport- 
 ed. Let A B C D,/g\ 66., be the feet. The base on which 
 it stands is A B C D, and the centre of gravity is nearly over 
 the point O, where the diagonals cross each other. The legs 
 A and C being raised together, the centre of gravity is sup- 
 ported by the legs B and D, since it falls between them ; and 
 when B and D are raised, it is, in like manner, supported by 
 the feet A and C. The centre of gravity, however, is often 
 unsupported for a moment ; for the leg B is raised from the 
 ground before A comes to it, as is plain from observing the 
 track of a horse's feet, the mark of A being upon or before 
 that of B. In the more rapid paces of all animals the centre 
 of gravity is at intervals unsupported. 
 
 The feats of rope-dancers are experiments on the manage- 
 ment of the centre of gravity. The evolutions of the perform- 
 er are found to be facilitated by holding in his hand a heavy 
 pole. His security in this case depends, not on the centre 
 of gravity of his body, but on that of his body and the pole 
 taken together. This point is near the centre of the pole, so 
 that, in fact, he may be said to hold in his hands the point on 
 the position of which the facility of his feats depends. With- 
 out the aid of the pole, the centre of gravity would be within 
 the trunk of the body, and its position could not be adapted 
 to circumstances with the same ease and rapidity. 
 
 (170.) The centre of gravity of a mass of fluid is that point 
 which would have the properties which have been proved to 
 belong to the centre of gravity of a solid, if the fluid were 
 solidified without changing in any respect the quantity or ar- 
 rangement of its parts. This point also possesses other prop- 
 erties, in reference to fluids, which will be investigated in 
 HYDROSTATICS and PNEUMATICS. 
 
 (171.) The centre of gravity of two bodies separated from 
 one another, is that point which would possess the properties 
 ascribed to the centre of gravity, if the two bodies were 
 uiiiicd bv an inflexible line, the weight of which might be neg- 
 lected. To find this point mathematically is a very simple 
 
CHAP. IX. CENTRE OF GRAVITY OF A SYSTEM. 105 
 
 problem. Let A and B, fig. 67., be the two bodies, and a 
 and b their centres of gravity. Draw the right line a b, and 
 divide it at C, in such a manner that a C shall have the same 
 proportion to 6 C as the mass of the body B has to the mass 
 of the body A. 
 
 This may easily be verified experimentally. Let A and B 
 be two bodies, whose weight is considerable, in comparison 
 with that of the rod a b, which joins them. Let a fine silken 
 string, with its ends attached to them, be hung upon a pin ; 
 and on the same pin let a plumb-line be suspended. In what- 
 ever position the bodies may be hung, it will be observed 
 that the plumb-line will cross the rod a b at the same point, 
 and that point will divide the line a b into parts a C arvl 
 b C, which are in the proportion of the mass of B to the 
 mass of A. 
 
 (172.) The centre of gravity of three separate bodies is 
 defined in the same manner as that of two, and may be found 
 by first determining the centre of gravity of two, and then 
 supposing their masses concentrated at that point, so as to 
 form one body, and finding the centre of gravity of that and 
 the third. 
 
 In the same manner the centre of gravity of any number 
 of bodies may be determined. 
 
 (173.) If a plate of uniform thickness be bounded by 
 straight edges, its centre of gravity may be found by dividing 
 it into triangles by diagonal lines, as in Jig. 68., and, having 
 determined by (154) the centres of gravity of the several 
 triangles, the centre of gravity of the whole plate will be 
 their common centre of gravity found as above. 
 
 (174.) Although the centre of gravity takes its name from 
 the familiar properties which it has in reference to detached 
 bodies of inconsiderable magnitude, placed on or near the sur- 
 face of the earth, yet it possesses properties of a much more 
 general and not less important nature. One of the most 
 remarkable of these is, that the centre of gravity of any num- 
 ber of separate bodies is never affected by the mutual attrac- 
 tion, impact, or other influence which the bodies may trans- 
 mit from one to another. This is a necessary consequence 
 of the equality of action and reaction explained in Chapter IV. 
 For if A and B, fg. 67., attract each other, and change 
 their places to A' B',the space a a' will have to b b 1 the same 
 proportion as B has to A, and, therefore, by what has just 
 been proved (171), the same proportion as a C has to b C 
 
106 THE ELEMENTS OF MECHANICS. CHAP. IX. 
 
 It follows that the remainders ul C and b' C will be in the 
 proportion of B to A, and that C will continue to be the 
 centre of gravity of the bodies after they have approached by 
 their mutual attraction. 
 
 Suppose, for example, that A and B were 12 Ibs. and 8 Ibs. 
 respectively, and that a b were 40 feet. The point C must 
 (171) divide a b into two parts, in the proportion of 8 to 12, 
 or of 2 to 3. Hence it is obvious that a C will be 16 feet, 
 and b C 24 feet. Now, suppose that A and B attract each 
 other, and that A approaches B through two feet. Then B 
 must approach A through three feet. Their distances from 
 tr will now be 14 feet and 21 feet, which, being in the pro- 
 portion of B to A, the point C will still be their centre of 
 gravity. 
 
 Hence it follows, that if a system of bodies, placed at rest, 
 be permitted to obey their mutual attractions, although the 
 bodies will thereby be severally moved, yet their common 
 centre of gravity must remain quiescent. 
 
 (175.) When one of two bodies is moving in a straight 
 line, the other being at rest, their common centre of gravity 
 must move in a parallel straight line. Let A and B,Jig. 69., 
 be the centres of gravity of the bodies, and let A move from 
 A to a, B remaining at rest. Draw the lines A B and a B. 
 In every position which the body B assumes during its motion, 
 the centre of gravity C divides the line joining them into 
 parts A C, B C, which are in the proportion of the mass B 
 to the mass A. Now, suppose any number of lines drawn 
 from B to the line A a ; a parallel C c to A a through C di- 
 vides all these .?ines in the same proportion ; and therefore, 
 while the body A moves from A to a, the common centre 
 of gravity moves from C to c. 
 
 If both the bodies A and B moved uniformly in straight 
 lines, the centre of gravity would have a motion compounded 
 (74) of the two motions with which it would be affected, 
 if each moved while the other remained at rest. In the 
 same manner, if there were three bodies, each moving uniform- 
 ly in a straight line, their common centre of gravity would 
 have a motion compounded of that motion which it would have 
 if one remained at rest while the other two moved, and that 
 which the motion of the first would give it if the last two 
 remained at rest ; and in the same manner it may be proved, 
 that when any number of bodies move each in a straight 
 line, their common centre of gravity will have a motion com 
 
CHAP. IX. ROTATORY AND PROGRESSIVE MOTION. 107 
 
 pounded of the motions which it receives from the bodies 
 severally. 
 
 It may happen that the several motions which the centre 
 of gravity receives from the hodies of the system will neutral- 
 ize each other ; and this does, in fact, take place for such 
 motions as are the consequences of the mutual action of the 
 bodies upon one another. 
 
 (176.) If a system of bodies be not under the immediate 
 influence of any forces, and their mutual attraction be con- 
 ceived to be suspended, they must severally be either at rest 
 or in uniform rectilinear motion in virtue of their inertia. 
 Hence their common centre of gravity must also be either 
 at rest or in uniform rectilinear motion. Now, if we suppose 
 their mutual attractions to take effect, the state of their com- 
 mon centre of gravity will not be changed, but the bodies 
 will severally receive motions compounded of their previous 
 uniform rectilinear motions and those which result from their 
 mutual attractions. The combined effects will cause each 
 body to revolve in an orbit round the common centre of grav- 
 ity, or will precipitate it towards that point. But still that 
 point will maintain its former state undisturbed. 
 
 This constitutes one of the general laws of mechanical 
 science, and is of great importance in physical astronomy. 
 It is known by the title " the conservation of the motion of 
 the centre of gravity." { 
 
 (177.) The solar system is an instance of the class of phe, 
 nomena to which we have just referred. All the motions 
 of the bodies which compose it can be traced to certain uni- 
 form rectilinear motions, received from some former impulse, 
 or from a force whose action has been suspended, and those mo- 
 tions which necessarily result from the principle of gravitation. 
 But we shall not here insist further on this subject, which 
 more properly belongs to another department of the science. 
 
 (178.) If a solid body suffer an impact in the direction 
 of a line passing through its centre of gravity, all the parti- 
 cles of the body will be driven forward with the same velocity 
 in lines parallel to the direction of the impact, and the whole 
 force of the motion will be equal to that of the impact. The 
 common velocity of the parts of the body will in this case be 
 determined by the principles explained in Chapter IV. The 
 impelling force being equally distributed among all the parts, 
 the velocity will be found by dividing the numerical value of 
 that force by the number expressing the mass. 
 
108 THE ELEMENTS OF MECHANICS. CHAP. X 
 
 If any number of impacts be given simultaneously to dif- 
 ferent points of a body, a certain complex motion will gener- 
 ally ensue. The mass will have a relative motion round the 
 centre of gravity as if it were fixed, while that point will 
 move forward uniformly in a straight line, carrying the body 
 with it. The relative motion of the mass round the centre 
 of gravity may be found by considering the centre of gravity 
 as a fixed point, round which the mass is free to move, 
 and then determining the motion which the applied forces 
 would produce. This motion being supposed to continue 
 uninterrupted, let all the forces be imagined to be ap- 
 plied in their proper directions and quantities to the centre 
 of gravity. By the principles for the composition of force 
 they will be mechanically equivalent to a single force through 
 that point. In the direction of this single force the centre 
 of gravity will move, and have the same velocity as if the 
 whole mass were there concentrated and received the impel- 
 ling forces. 
 
 (179.) These general properties, which are entirely inde- 
 pendent of gravity, render the " centre of gravity" an inade- 
 quate title for this important point. Some physical writers 
 have, consequently, called it the " centre of inertia." The 
 " centre of gravity," however, is the name by which it is still 
 generally designated. 
 
 CHAPTER X. 
 
 THE MECHANICAL PROPERTIES OF AN AXIS. 
 
 (180.) WHEN a body has a motion of rotation, the line 
 round which it revolves is called an axis. Every point of the 
 body must in this case move in a circle, whose centre lies 
 in the axis, and whose radius is the distance of the point from 
 the axis. Sometimes while the body revolves, the axis itself 
 is movable, and not unfrequently in a state of actual motion. 
 The motions of the earth and planets, or that of a common 
 spinning-top, are examples of this. The cases, however, 
 which will be considered in the .present chapter, are chiefly 
 those in which the axis is immovable, or at least where its 
 motion has no relation to the phenomena under investigation. 
 Instances of this are so frequent and obvious, that it seems 
 
CHAP. X. PROPERTIDS OF AN AXIS. 109 
 
 scarcely necessary to particularize them. Wheel-work of 
 every description, the moving parts of watches and clocks, 
 turning lathes, mill-work, doors and lids on hinges, are all 
 obvious examples. In tools or other instruments which work 
 on joints or pivots, such as scissors, shears, pincers, although 
 the joint or pivot be not absolutely fixed, it is to be considered 
 so in reference to the mechanical effect. 
 
 In some cases, as in most of the wheels of watches and 
 clocks, fly-wheels and chucks of the turning lathe, and the 
 arms of wind-mills, the body turns continually in the same 
 direction, and each of its points traverses a complete circle 
 during every revolution of the body round its axis. In other 
 instances, the motion is alternate or reciprocating, its direction 
 being at intervals reversed. Such is the case in pendulums 
 of clocks, balance-wheels of chronometers, the treddle of the 
 lathe, doors and lids on hinges, scissors, shears, pincers, &,c. 
 When the alternation is constant and regular, it is called 
 oscillation or vibration, as in pendulums and balance-wheels. 
 
 (181.) To explain the properties of an axis of rotation, it 
 will be necessary to consider the different kinds of forces, to 
 the action of which a body movable on such an axis may be 
 submitted, to show how this action depends on their several 
 quantities and directions, to distinguish the cases in which 
 the forces neutralize each other, and mutually equilibrate from 
 those in which motion ensues, to determine the effect which 
 the axis suffers, and, in the cases where motion is produced, 
 to estimate the effects of those centrifugal forces (137.) which 
 are created by the mass of the body whirling round the axis. 
 
 Forces in general have been distinguished, by the duration 
 of their action, into instantaneous and continued forces. The 
 effect of an instantaneous force is produced in an infinitely 
 short time. If the body which sustains such an action be 
 previously quiescent and free, it will move with a uniform 
 velocity in the direction of the impressed force. (93.) If, 
 on the other hand, the body be not free, but so restrained 
 that the impulse cannot put it in motion, then the fixed points 
 or lines which resist the motion sustain a corresponding shock 
 at the moment of the impulse. This effect, which is called 
 percussion, is, like the force which causes it, instantaneous. 
 
 A continued force produces a continued effect. If the 
 body be free and previously quiescent, this effect is a con- 
 tinual increase of velocity. If the body be so restrained 
 that the appfced force cannot put it in motion, the effect is 
 10 
 
110 THE ELEMENTS OF MECHANICS. CHAP. X. 
 
 a continued pressure on the points or lines which sustain 
 it. (94.) 
 
 It may happen, however, that although the body be not 
 absolutely free to move in obedience to the force applied to 
 it, yet still it may not be altogether so restrained as to resist 
 the effect of that force, and remain at rest. If the point at 
 which a force is applied be free to move in a certain direction 
 not coinciding with that of the applied force, that force will 
 be resolved into two elements ; one of which is in the direc- 
 tion in which the point is free to move, and the other at right 
 angles to that direction. The point will move in obedience 
 to the former element, and the latter will produce percussion 
 or pressure on the points or lines which restrain the body. 
 In fact, in such cases, the resistance offered by the circum- 
 stances which confine the motion of the body modifies the 
 motion which it receives, and, as every change of motion must 
 be the consequence of a force applied (44.), the fixed points 
 or lines which offer the resistance must suffer a corresponding 
 effect. 
 
 It may happen that the forces impressed on the body, 
 whether they be continued or instantaneous, are such as, 
 were it free, would communicate to it a motion which the 
 circumstances which restrain it do not forbid it to receive. 
 In such a case, the fixed points or lines which restrain the 
 body sustain no force, and the phenomena will be the same 
 in all respects as if these points or lines were not fixed. 
 
 It will be easy to apply these general reflections to the case 
 in which a solid body is movable on a fixed axis. Such a 
 body is susceptible of no motion except one of rotation on 
 that axis. If it be submitted to the action of instantaneous 
 forces, one or other of the following effects must ensue. 
 
 1. The axis may resist the forces, and prevent any motion. 
 
 2. The axis may modify the effect of the forces sustaining 
 a corresponding percussion, and the body receiving a motion 
 of rotation. 3. The forces applied may be such as would 
 cause the body to spin round the axis even were it not fixed, 
 in which case the body will receive a motion of rotation, but 
 the axis will suffer no percussion. 
 
 What has been just observed of the effect of instantaneous 
 forces is likewise applicable to continued ones. 1. The axis 
 may entirely resist the effect of such forces, in which case 
 it will suffer a pressure which may be estimated by the rules 
 for the composition of force. 2. It may modify the effect 
 
CHAP. X. PROPERTIES OP AN AXIS. Ill 
 
 of the applied forces, in which case it must also sustain a 
 pressure, and the body must receive a motion of rotation 
 which is subject to constant variation, owing to the incessant 
 action of the forces. 3. The forces may be such as would 
 communicate to the body the same rotatory motion if the 
 axis were not fixed. In this case, the forces will produce no 
 pressure on the axis. 
 
 The impressed forces are not the only causes which affect 
 the axis of a body during the phenomenon of rotation. 
 This species of motion calls into action other forces depend- 
 ing on the inertia of the mass, which produce effects upon 
 the axis, and which play a prominent part in the theory of 
 rotation. While the body revolves on its axis, the component 
 particles of its mass move in circles, the centres of which 
 are placed in the axis. The radius of the circle in which 
 each particle moves is the line drawn from that particle 
 perpendicular to the axis. It has been already proved that a 
 particle of matter, having a circular motion, is attended with 
 a centrifugal force proportionate to the radius of the circle 
 in which it moves and to the square of its angular velocity. 
 When a solid body revolves on its axis, all its parts are whirled 
 round together, each performing a complete revolution in the 
 same time. The angular velocity is consequently the same 
 for all, and the difference of the centrifugal forces of differ- 
 ent particles must entirely depend upon their distances from 
 the axis. The tendency of each particle to fly from the 
 axis, arising from the centrifugal force, is resisted by the 
 cohesion of the parts of the mass, and, in general, this ten- 
 dency is expended in exciting a pressure or strain upon the 
 axis. It ought to be recollected, however, that this pressure 
 or strain is altogether different from that already mentioned, 
 and produced by the forces which give motion to the body. 
 The latter depends entirely upon the quantity arid directions 
 of the applied forces in relation to the axis ; the former de- 
 pends on the figure and density of the body, and the velocity 
 of its motion. 
 
 These very complex effects render a simple and elementary 
 exposition of the mechanical properties of a fixed axis a 
 matter of considerable difficulty. Indeed, the complete 
 mathematical developement of this theory long eluded the 
 skill of the most acute geometers; and it was only at a 
 comparatively late period that it yielded to the searching 
 analysis of modern science. 
 
112 THE ELEMENTS OF MECHANICS. CHAP. X. 
 
 (182.) To commence with the most simple case, we shall 
 consider the body as submitted to the action of a single force. 
 The effect of this force will vary according to the relation of 
 its direction to that of the axis. There are two ways in 
 which a body may be conceived to be movable around an axis. 
 1. By having pivots at two points which rest in sockets, so 
 that, when the body is moved, it must revolve round the right 
 line, joining the pivots as an axis. 2. A thin cylindrical rod 
 may pass through the body, on which it may turn in the 
 same manner as a wheel upon its axle. 
 
 If the force be applied to the body in the direction of the 
 axis, it is evident that no motion can ensue, and the effect 
 produced will be a pressure on that pivot towards which the 
 force is directed. If, in this case, the body revolved on a 
 cylindrical rod, the tendency of the force would be to make 
 it slide along the rod without revolving round it. 
 
 Let us next suppose the force to be applied, not in the di- 
 rection of the axis itself, but parallel to it. Let A B,Jig. 70., 
 be the axis, and let C D be the direction of the force applied. 
 The pivots being supposed to be at A and B, draw A G and 
 B F perpendicular to A B. The force C D will be equiva- 
 lent to three forces, one acting from B towards A, equal in 
 quantity to the force C D. This force will evidently produce 
 a corresponding pressure on the pivot A. The other two 
 forces will act in the directions A G and B F, and will have 
 respectively to the force C D the same proportion as A E has 
 to A B. Such will be the mechanical effect of a force C D 
 parallel to the axis. And as these effects are all directed on 
 the pivots, no motion can ensue. 
 
 If the body revolve on a cylindrical rod, the forces A G 
 and B F would produce a strain upon the axis, while the 
 third force in the direction B A would have a tendency to 
 make the body slide along it. 
 
 (183.) If the force applied to the body be directed upon 
 the axis, and at right angles to it, no motion can be produced. 
 In this case, if the body be supported by pivots at A and B, 
 the force K L, perpendicular to the line A B, will be distrib- 
 uted between the pivots, producing a pressure on each pro- 
 portional to its distance from the other ; the pressure on A 
 having to the pressure on B the same proportion as L B has 
 to L A. 
 
 If the force K H be directed obliquely to the axis, it will 
 be equivalent to two forces (76.), one K L perpendicular to 
 
CHAP. X. PROPERTIES OF AN AXIS. 113 
 
 the axis, and the other K M parallel to it. The effect of 
 each of these may be investigated as in the preceding cases. 
 
 In all these observations the body has been supposed to be 
 submitted to the action of one force only. If several forces 
 act upon it, the direction of each of them crossing the axis 
 either perpendicularly or obliquely, or taking the direction of 
 the axis or any parallel direction, their effects may be similar- 
 ly investigated. In the same manner we may determine the 
 effects of any number of forces whose combined results are 
 mechanically equivalent to forces which either intersect the 
 axis or are parallel to it. 
 
 (184.) If any force be applied whose direction lies in a 
 plane oblique to the axis, it can always be resolved into two 
 elements (76.), one of which is parallel to the axis, and the 
 other in a plane perpendicular to it. The effect of the for- 
 mer has been already determined, and therefore we shall at 
 present confine our attention to the latter. 
 
 Suppose the axis to be perpendicular to the paper, and to 
 pass through the point G, fi.g. 71., and let A B C be a section 
 of the body. It will be convenient to consider the section 
 vertical and the axis horizontal, omitting, however, any notice 
 of the effect of the weight of the body. 
 
 Let a weight W be suspended by a cord Q, W from any 
 point Q. This weight will evidently have a tendency to 
 turn the body round in the direction ABC. Let another 
 cord be attached to any other point P, and, being carried over 
 a wheel R, let a dish S be attached to it, and let fine sand 
 be poured into this dish until the tendency of S to turn the 
 body round the axis in the direction of C B A balances the 
 opposite tendency of W. Let the weights of W and S be 
 then exactly ascertained, and also let the distances G I and 
 G H of the cords from the axis be exactly measured. It will 
 be found that, if the number of ounces in the weight S be 
 multiplied by the number of inches in G H, and also the 
 number of ounces in W by the number of inches in G I, 
 equal products will be obtained. This experiment may be 
 varied by varying the position of the wheel R, and thereby 
 changing the direction of the string P R, in which cases it 
 will be always found necessary to vary the weight of S in 
 such a manner, that when the number of ounces in it is mul- 
 tiplied by the number of inches in the distance of the string 
 from the axis, the product obtained shall be equal to that of 
 the weiorht W by the distance G I. We have here used 
 10* 
 
114 THE ELEMENTS OF MECHANICS. CHAP. X. 
 
 ounces and inches as the measures of weight and distance ; 
 but it is obvious that any other measures would be equally 
 applicable. 
 
 From what has been just stated it follows, that the energy 
 of the weight of S to move the body on its axis, docs not de- 
 pend alone upon the actual amount of that weight, but also 
 upon the distance of the string from the axis. If, while the 
 position of the string remains unaltered, the weight of S be 
 increased or diminished, the resisting weight W must be in- 
 creased or diminished in the same proportion. But if while 
 the weight of S remains unaltered, the distance of the string 
 P R from the axis G be increased or diminished, it will be 
 found necessary to increase or diminish the resisting weight 
 W in exactly the same proportion. It therefore appears that 
 the increase or diminution of the distance of the direction 
 of a force from the axis has the same effect upon its power 
 to give rotation as a similar increase or diminution of the 
 force itself. The power of a force to produce rotation is, 
 therefore, accurately estimated, not by the force alone, but 
 by the product found by multiplying the force by the distance 
 of its direction from the axis. It is frequently necessary in 
 mechanical science to refer to this power of a force, and, 
 accordingly, the product just mentioned has received a par- 
 ticular denomination. It is called the moment of the force 
 round the axis. 
 
 (185.) The distance of the direction of a force from the 
 axis is sometimes called the leverage of the force. The mo- 
 ment of a force is, therefore, found by multiplying the force 
 by its leverage, and the energy of a given force to turn a 
 body round an axis is proportional to the leverage of that 
 force. 
 
 From all that has been observed, it may easily be inferred 
 that, if several forces affect a body movable on an axis, having 
 tendencies to turn it in different directions, they will mutu- 
 ally neutralize each other and produce equilibrium, if the 
 sum of the moments of those forces which tend to turn the 
 body in one direction be equal to the sum of the moments of 
 Jjiose which tend to turn it in the opposite direction. Thus, 
 if the forces A, B, C, . . . tend to turn the body from right to 
 left, and the distances of their directions from the axis be 
 , b, c, . . . and the forces A', B', C', . . . tend to move it from 
 left to right, and the distances of their directions from the 
 axis be a', b', c', . . . ; then these forces will produce equilib- 
 
CHAP. X. MOTION ROUND AN AXIS. 115 
 
 rium, if the products found by multiplying the ounces in 
 A, B, C, . . . respectively by the inches in <z, 6, e, . . . when 
 added together, be equal to the products found by multiplying 
 the ounces in A', B', C', . . . by the inches in a', &', c 1 , . . 
 respectively when added together. But if either of these 
 sets of products when added together exceed the other, the 
 corresponding set of forces will prevail, and the body will 
 Devolve on its axis. 
 
 (186.) When a body receives an impulse in a direction 
 perpendicular to the axis, but not crossing it, a uniform rotato- 
 ry motion is produced. The velocity of this motion depends 
 on the force of the impulse, the distance of the direction of 
 the impulse from the axis, and the manner in which the mass 
 of the body is distributed round the axis. It is to be con- 
 sidered that the whole force of the impulse is shared amongst 
 the various parts of the mass, and is transmitted to them 
 from the point where the impulse is applied by reason of the 
 cohesion and tenacity of the parts, and the impossibility of 
 one part yielding to a force without carrying all the other 
 parts with it. The force applied acts upon those particles 
 nearer to the axis than its own direction under advantageous 
 circumstances ; for, according to what has been already ex- 
 plained, their power to resist the effect of the applied force 
 is small in the same proportion with their distance. On the 
 other hand, the applied force acts upon particles of the mass, 
 at a greater distance than its own direction, under circum- 
 stances proportionably disadvantageous; for their resistance 
 to the applied force is great in proportion to their distances 
 from the axis. 
 
 Let C D, Jig. 72., be a section of the body by a plane 
 passing through the axis A B. Suppose the impulse to be 
 applied at P, perpendicular to this plane, and at the distance 
 P O from the axis. The effect of the impulse being distrib- 
 uted through the mass will cause the body to revolve on A B 
 with a uniform velocity. There is a certain point G, at 
 which, if the whole mass were concentrated, it would receive 
 from the impulse the same velocity round the axis. The dis- 
 tance O G is called the radius^of gyration of the axis A B, 
 and the point G is called the centre of gyration relatively to 
 that axis. The effect of the impulse upon the mass concen- 
 trated at G is great in exactly the same proportion as O G is 
 small. This easily follows from the property of moments, 
 
116 
 
 THE ELEMENTS OF MECHANICS. CHAP. X 
 
 which has been already explained ; from whence it may be 
 inferred, that the greater the radius of gyration is, the less 
 willj>e the velocity which the body will receive from a given 
 impulse. 
 
 (187.) Since the radius of gyration depends on the manner 
 in which the mass is arranged round the axis, it follows that 
 for different axes in the same body there will be different 
 radii of gyration. Of allaxes taken in the same body par- 
 allel to each other, that which passes through the centre of 
 gravity has the least radius of gyration. If the radius of 
 gyration of any axis passing through the centre of gravity l><* 
 given, that of any parallel axis can be found ; for the square 
 of the radius of gyration of any axis is equal to the square 
 of the distance of that axis from the centre of gravity added 
 to the square of the radius of gyration of the parallel axis 
 through the centre of gravity. 
 
 (188.) The product of the numerical expressions for the 
 mass of the body and the square of the radius of gyration is 
 a quantity much used in mechanical science, and has been 
 called the moment of inertia. The moments of inertia, 
 therefore, for different axes in the same body, are proportional 
 to the squares of the corresponding radii of gyration, and, 
 consequently, increase as the distances of the axes from the 
 centre of gravity increase (187). 
 
 (189.) From what has been explained in (187.), it follows, 
 that the moment of inertia of any axis may be computed by 
 common arithmetic, if the moment of inertia of a parallel 
 axis through the centre of gravity be previously known. To 
 determine this last, however, would require analytical pro- 
 cesses altogether unsuitable to the nature and objects of the 
 present treatise. 
 
 The velocity of rotation which a body receives from a 
 given impulse is great in exactly the same proportion as the 
 moment of inertia is small. Thus the moment of inertia 
 may be considered in rotatory motion analogous to the mass 
 of the body in rectilinear motion. 
 
 From what has been explained in (187.) it follows that a 
 given impulse at a given distance from the axis will commu- 
 nicate the greatest angular velocity when the axis passes 
 through the centre of gravity, and that the velocity which it 
 will communicate round other axes will be diminished in the 
 same proportion as the squares of their distances from the 
 
CHAP. X. PRINCIPAL AXES. 117 
 
 centre of gravity, added to the square of the radius of gyra- 
 tion for a parallel axis through the centre of gravity, are 
 augmented. 
 
 (190.) If any point whatever he assumed in a body, and 
 right lines be conceived to diverge in all directions from that 
 point, there are generally two of these lines, which, being 
 taken as axes of rotation, one has a greater and the other a 
 less moment of inertia than any of the others. It is a re- 
 markable circumstance, that whatever be the nature of the 
 body, whatever be its shape, and whatever be the position of 
 the point assumed, these two axes of greatest and least mo- 
 ment will always be at right angles to each other. 
 
 These axes and a third through the same point, and at 
 right angles to both of them, are called the principal axes 
 of that point from which they diverge. To form a distinct 
 notion of their relative position, let the axis of greatest mo- 
 ment be imagined to lie horizontally from north to south, and 
 the axis of least moment from east to west ; then the third 
 principal axis will be presented perpendicularly upwards and 
 downwards. The first two being called the principal axes of 
 greatest and least moment, the third may be called the inter- 
 mediate principal axis. 
 
 (191.) Although the moments of the three principal axes 
 be in general unequal, yet bodies may be found having cer- 
 tain axes for which these moments may be equal. In some 
 cases, the moment of the intermediate axis is equal to that of 
 the principal axis of greatest moment : in others, it is equal to 
 that of the principal axis of least moment, and in others the 
 moments of all the three principal axes are equal to each 
 other. 
 
 If the moments of any two of three principal axes be equal, 
 the moments of all axes through the same point and in their 
 plane will also be equal ; and if the moments of the three 
 principal axes through a point be equal, the moments of all 
 axes whatever, through the same point, will be equal. 
 
 (192.) If the moments of the principal axes through the 
 centre of gravity be known, the moments for all other axes 
 through that point may be easily computed. To effect this 
 it is only necessary to multiply the moments of the principal 
 axes by the squares of the co-sines of the angles formed by 
 them respectively with the axis whose moment is sought. 
 The products, being added together, will give the required 
 moment. 
 
THE ELEMENTS OF MECHANICS. CHAP. X. 
 
 (193.) By combining this result with that of (189.), it will 
 be evident that the moment of all axes whatever may be de- 
 termined, if those of the principal axes through the centre 
 of gravity be known. 
 
 (194.) It is obvious that the principal axis of least moment 
 through the centre of gravity has a less moment of inertia 
 than any other axis whatever. For it has, by its definition 
 (190.), a less moment of inertia than any other axis through 
 Ihe centre of gravity, and every other axis through the cen- 
 tre of gravity has a less moment of inertia than a parallel 
 axis through any other point (1H7.) and (189.). 
 
 (195.) If two of the principal axes through the centre of 
 gravity have equal moments of inertia, all axes in any plane 
 parallel to the plane of these axes, and passing through the 
 point where a perpendicular from the centre of gravity meets 
 that plane, must have equal moments of inertia. For by 
 (191.) all axes in the plane of those two have equal moments, 
 and by (189.) the axes in the parallel plane have moments 
 which exceed these by the same quantity, being equally dis- 
 tant from them. (187.) 
 
 Hence it is obvious that if the three principal axes through 
 the centre of gravity have equal moments, all axes situated 
 in any given plane, and passing through the point where the 
 perpendicular from the centre of gravity meets that plane, 
 will have equal moments, being equally distant from parallel 
 axes through the centre of gravity. 
 
 (190.) If the three principal axes through the centre of 
 gravity have unequal moments, there is no point whatever for 
 which all axes will have equal moments ; but if the principal 
 axis of least moment and the intermediate principal axis 
 through the centre of gravity have equal moments, then 
 there will be two points on the principal axis of greatest mo- 
 ment, equally distant at opposite sides of the centre of gravity, 
 at which all axes will have equal moments. If the three 
 principal axes through the centre of gravity have equal mo- 
 ments, no other point of the body can have principal axes of 
 equal moment. 
 
 (197.) When a body revolves on a fixed axis, the parts of 
 its mass are whirled in circles round the axis ; and since they 
 move with a common angular velocity, they will have centrifu- 
 gal forces proportional to their distances from the axis. If 
 the component parts of the mass were not united together by 
 cohesive forces of energies greater than these centrifugal 
 
CHAP. X. PRESSURE UPON AN AXIS. 119 
 
 forces, they would be separated, and would fly off from the 
 axis ; but their cohesion prevents this, and causes the effects 
 of the different centrifugal forces, which affect the different 
 parts of the mass, to be transmitted so as to modify each other, 
 and finally to produce one or more forces mechanically equiva- 
 lent to the whole, and which are exerted upon the axis and 
 resisted by it. We propose now to explain these effects, as 
 far as it is possible to render them intelligible without the aid 
 of mathematical language. 
 
 It is obvious that any number of equal parts of the mass, 
 which are uniformly arranged in a circle round the axis, have 
 equal centrifugal forces acting from the centre of the circle 
 in every direction. These mutually neutralize each other, 
 and therefore exert no force on the axis. The same may be 
 said of all parts of the mass which are regularly and equally 
 distributed on every side of the axis. 
 
 Also, if equal masses be placed at equal distances on oppo- 
 site sides of the axis, their centrifugal forces will destroy each 
 other. Hence it appears that the pressure which the axis of 
 rotation sustains from the centrifugal forces of the revolving 
 mass, arises from the unequal distribution of the matter 
 around it. 
 
 From this reasoning it will be easily perceived that, in the 
 following examples, the axis of rotation will sustain no pres- 
 sure. 
 
 A globe revolving on any of its diameters, the density be- 
 ing the same at equal distances from the centre. 
 
 A spheroid or a cylinder revolving on its axis, the density 
 being equal at equal distances from the axis. 
 
 A cube revolving on an axis which passes through the cen- 
 tre of two opposite bases, being of uniform density. 
 
 A circular plate of uniform thickness and density revolving 
 on one of its diameters as an axis. 
 
 (198.) In all these examples, it will be observed that the 
 axis of rotation passes through the centre of gravity. The 
 general theorem, of which they are only particular instances, 
 is, " If a body revolve on a principal axis, passing through 
 the centre of gravity, the axis will sustain no pressure from 
 the centrifugal force of the revolving mass." This is a prop- 
 erty in which the principal axes through the centre of gravity 
 are unique. There is no other axis on which a body could 
 revolve without pressure. 
 
 If two of the principal axes through the centre of gravity 
 
120 THE -ELEMENTS OF MECHANICS. CHAP. x. 
 
 have equal moments, every axis in their plane has the same 
 moment, and is to be considered equally as a principal axis. 
 In this case, the body would revolve on any of these axes with- 
 out pressure. 
 
 A homogeneous spheroid furnishes an example of this. If 
 any of the diameters of the earth's equator were a fixed axis, 
 the earth would revolve on it without producing pressure. 
 
 If the three principal axes through the centre of gravity 
 have equal moments, all axes through the centre of gravity 
 are to be considered as principal axes. In this case, the body 
 would revolve without pressure on any axis through the cen- 
 tre of gravity. 
 
 A globe, iii which the density of the mass at equal distances 
 from the centre is the same, is an example of this. Such a 
 body would revolve without pressure on any axis through its 
 centre. 
 
 (199.) Since no pressure is excited on the axis in these 
 cases, the state of the body will not be changed, if, during its 
 rotation, the axis cease to be fixed. The body will, notwith- 
 standing, continue to revolve round the axis, and the axis will 
 maintain its position. 
 
 Thus a spinning-top of homogeneous material and sym- 
 metrical form will revolve steadily in the same position, until 
 the friction of its point with the surface on which it rests de- 
 prives it of motion. This is a phenomenon which can only 
 be exhibited when the axis of rotation is a principal axis 
 through the centre of gravity. 
 
 (200.) If the body revolve round any axis through the cen- 
 tre of gravity, which is not a principal axis, the centrifugal 
 pressure is represented by two forces, which are equal and 
 parallel, but which act in opposite directions on different points 
 of the axis. The effect of these forces is to produce a strain 
 upon the axis, and give the body a tendency to move round 
 another axis at right angles to the former. 
 
 . (201.) If the fixed axis on which a body revolves be a 
 principal axis through any point different from the centre of 
 gravity, then a pressure will be produced by the centrifugal 
 force of the revolving mass, and this pressure will act at right 
 angles to the axis on the point to which it is a principal axis, 
 and in the plane through that axis and the centre of gravity. 
 The amount of the pressure will be proportional to the mass 
 of the body, the distance of the centre of gravity from the 
 axis, and the square of the velocity of rotation. 
 
CHAP. X. PRESSURE UPON AN AXIS. 121 
 
 (1202.) Since the whole pressure is in this case excited on 
 a single point, the stability of the axis will not be disturb- 
 ed, provided that point alone be fixed. So that, even though 
 the axis should be free to turn on that point, no motion will 
 ensue as long as no external forces act upon the body. 
 
 (203.) If the axis of rotation be not a principal axis, the 
 centrifugal forces will produce an effect which cannot be rep- 
 resented by a single force. The effect may be understood by 
 conceiving two forces to act on different points of the axis at 
 right angles to it and to each other. The quantities of these 
 pressures and their directions depend on the figure and density 
 of the mass and the position of the axis, in a manner which 
 cannot be explained without the aid of mathematical language 
 and principles. 
 
 (204.) The effects upon the axis which have been now ex- 
 plained are those which arise from the motion of rotation, 
 from whatever cause that motion may have arisen. The 
 forces which produce that motion, however, are attended with 
 effects on the axis which still remain to be noticed. When 
 these forces, whether they be of the nature of instantaneous 
 actions or continued forces, are entirely resisted by the axis, 
 their directions must severally be in a plane passing through 
 the axis, or they must, by the principles of the composition 
 of force [(74.) et seq.], be mechanically equivalent to forces 
 in that plane. In every other case, the impressed forces must 
 produce motion, and, except in certain cases, must also pro- 
 duce effects upon the axis. 
 
 By the rules for the composition of force it is possible in all 
 cases to resolve the impressed forces into others which are 
 either in planes through the axis, or in planes perpendicular 
 to it, or, finally, some in planes through it, and others in 
 planes perpendicular to it. The effect of those which are in 
 planes through the axis has been already explained ; and we 
 shall now confine our attention to those impelling forces 
 which act at right angles to the axis, and which produce motion. 
 
 It will be sufficient to consider the effect of a single force 
 at right angles to the axis ; for whatever be the number of 
 forces which act either simultaneously or successively, the 
 effect of the whole will be decided by combining their sepa- 
 rate effects, The effect which a single force produces, de- 
 pends on two circumstances 1. The position of the axis with 
 respect to the figure and mass of the body, and, 2. The quan- 
 tity and direction of the force itself. 
 11 
 
122 TIIE ELEMENTS OF MECHANICS. CHAP. X. 
 
 In general, the shock which the axis sustains from the im- 
 pact may be represented by two impacts applied to it at differ- 
 ent points, one parallel to the impressed force, and the other 
 perpendicular to it, but both perpendicular to the axis. There 
 are certain circumstances, however, under which this effect 
 will be modified. 
 
 If the impulse which the body receives be in a direction 
 perpendicular to a plane through the axis and the centre of 
 gravity, and at a distance from the axis which bears to the 
 radius of gyration (186.) the same proportion as that line bears 
 to the distance of the centre of gravity from the axis, there 
 are certain cases in which the impulse will produce no per- 
 cussion. To characterize these cases generally would require 
 analytical formula which cannot conveniently be translated 
 into ordinary language. That point of the plane, however, 
 where the direction of the impressed force meets it, when no 
 percussion on the axis is produced, is called the centre of 
 percussion. 
 
 If the axis of rotation be a principal axis, the centre of per- 
 cussion must be in the right line drawn through the centre of 
 gravity, intersecting the axis at right angles, and at the dis- 
 tance from the axis already explained. 
 
 If the axis of rotation be parallel to a principal axis through 
 the centre of gravity, the centre of percussion will be deter- 
 mined in the same manner. 
 
 (205.) There are many positions which the axis may have, 
 in which there will be no centre of percussion ; that is, there 
 will be no direction in which an impulse could be applied 
 without producing a shock upon the axis. One of these 
 positions is when it is a principal axis through the centre of 
 gravity. This is the only case of rotation round an axis, in 
 which no effect arises from the centrifugal force ; and there- 
 fore it follows that the only case in which the axis sustains no 
 effect from the motion produced, is one in which it must 
 necessarily suffer an effect from that which produces the mo- 
 tion. 
 
 If the body be acted upon by continued forces, their effect 
 is at each instant determined by the general principles for the 
 composition of force. 
 
CHAP. XI THE PENDULUM. 123 
 
 CHAPTER XI. 
 
 ON THE PENDULUM. 
 
 (206.) WHEN a body is placed on an horizontal axis which 
 does not pass through its centre of gravity, it will remain in 
 permanent equilibrium only when the centre of gravity is im- 
 mediately below the axis. If this point be placed in any other 
 situation, the body will oscillate from side to side, until the 
 atmospherical resistance and the friction of the axis destroy 
 its motion. (159,160.) Such a body is called a pendulum. 
 The swinging motion which it receives is called oscillation or 
 vibration. 
 
 (207.) The use of the pendulum, not only for philosophi- 
 cal purposes, but in the ordinary economy of life, renders it 
 a subject of considerable importance. It furnishes the most 
 exact means of measuring time, and of determining with 
 precision various natural phenomena. By its means the vari- 
 ation of the force of gravity in different latitudes is discover- 
 ed, and the law of that variation experimentally exhibited. 
 In the present chapter, we propose to explain the general 
 principles which regulate the oscillation of pendulums. Mi- 
 nute details concerning their construction will be given in the 
 twenty-first chapter of this volume. 
 
 (208.) A simple pendulum is composed of a heavy molecule 
 attached to the end of a flexible thread, and suspended by a 
 fixed point O, Jig. 73. When the pendulum is placed in the 
 position O C, the molecule being vertically below the point 
 of suspension, it will remain in equilibrium ; but if it be drawn 
 into the position O A, and there liberated, it will descend 
 towards C, moving through the arc A C with accelerated mo- 
 tion. Having arrived at C, and acquired a certain velocity, it 
 will, by reason of its inertia, continue to move in the same 
 direction. It will therefore commence to ascend the arc C A' 
 with the velocity so acquired. During its ascent, the weight 
 of the molecule retards its motion in exactly the same manner 
 as it had accelerated it in descending from A to C ; and when 
 the molecule has ascended through the arc C A' equal to C A, 
 its entire velocity will be destroyed, and it will cease to move 
 in that direction. It will thus be placed at A' in the same 
 manner as in 'the first instance it had been placed at A, and 
 
124 THE ELEMENTS OP MECHANICS. CHAP. XI 
 
 consequently it will descend from A' to C with accelerated 
 motion, in the same manner as it first moved from A to C. It 
 will then ascend from C to A, and so on continually. In 
 this case, the thread, by which the molecule is suspended, is 
 supposed to be perfectly flexible, inextensible, and of incon- 
 siderable weight. The point of suspension is supposed to be 
 without friction, and the atmosphere to offer no resistance to 
 the. motion. 
 
 It is evident from what has been stated, that the times of 
 moving from A to A' and from A' to A are equal, and will 
 continue to be equal so long as the pendulum continues to 
 vibrate. If the number of vibrations performed by the pen- 
 dulum were registered, and the time of each vibration known, 
 this instrument would become a chronometer. 
 
 The rate at which the motion of the pendulum is accele- 
 rated in its descent towards its lowest position is not uniform, 
 because the force which impels it is continually decreasing, 
 and altogether disappears at the point C. The impelling force 
 arises from the effect of gravity on the suspended molecule, 
 and this effect is always produced in the vertical direction A 
 V. The greater the angle O A V is, the less efficient the 
 force of gravity will be in accelerating the molecule : this 
 angle evidently increases as the molecule approaches C, which 
 will appear by inspecting jig.- 73. At C, the force of gravity 
 acting in the direction C-B is totally expended in giving ten- 
 sion to the thread, and is > inefficient in moving the molecule. 
 It follows, therefore, thai the impelling force is greatest at A, 
 and continually diminishes from A to C, where it altogether 
 vanishes. The same observations will be applicable to the re- 
 tarding force from C to A', and to the accelerating force from 
 A' to C, and so on. 
 
 When the length of the thread and the intensity of the 
 force of gravity are given, the time of vibration depends on 
 the length of the arc A C, or on the magnitude of the angle 
 A O C. If, however, this angle do not exceed a certain 
 limit of magnitude, the time of vibration will be subject to 
 no sensible variation, however that angle may vary. Thus 
 the time of oscillation will be the same, whether the angle 
 A O C be 2, or 1 30', or 1, or any lesser magnitude. This 
 property of a pendulum is expressed by the word isochronism. 
 The strict demonstration of this property depends on math- 
 ematical principles, the details of which would not be suita- 
 
CHAP. XI. THE PENDULUM. 125 
 
 ble to the present treatise. It is not difficult, however, to 
 explain generally how it happens that the same pendulum 
 will swing through greater and smaller arcs of vibration in 
 the same time. If it swing from A, the force of gravity at 
 the commencement of its motion impels it with an effect 
 depending on the obliquity of the lines O A and A V. If it 
 commence its motion from a, the impelling effect from the 
 force of gravity will be considerably less than at A ; conse- 
 quently, the pendulum begins to move at a slower rate, when 
 it swings from a than when it moves from A : the greater 
 magnitude of the swing is therefore compensated by the in- 
 creased velocity, so that the greater and the smaller arcs of 
 vibration are moved through in the same time. 
 
 (209.) To establish this property experimentally, it is only 
 necessary to suspend a small ball of metal, or other heavy 
 substance, by a flexible thread, and to put it in a state of 
 vibration, the entire arc of vibration not exceeding 4 or 5, 
 the friction -on the point of suspension and other causes will 
 gradually diminish the arc of vibration, so that, after the lapse 
 of some hours, it will be so small, that the motion will scarcely 
 be discerned without microscopic aid. If the vibration of 
 this pendulum be observed in reference to a correct time- 
 keeper, at the commencement, at the middle, and towards 
 the end of its motion, the rate will be found to suffer no 
 sensible change. 
 
 This remarkable law of isochronism was one of the earliest 
 discoveries of Galileo. It is said, that, when very young, he 
 observed a chandelier suspended from the roof of a church 
 in Pisa swinging with a pendulous motion, and was struck 
 with the uniformity of the rate, even when the extent of the 
 swing was subject to evident variation. 
 
 (210.) It has been stated in (117.) that the attraction of 
 gravity affects all bodies equally, and moves them with the 
 same velocity, whatever be the nature or quantity of the ma- 
 terials of which they are composed. Since it is the force 
 of gravity which moves the pendulum, we should therefore 
 expect that the circumstances of that motion should not be 
 affected either by the quantity or quality of the pendulous 
 body. And we find this, in fact, to be the case ; for if small 
 pieces of different heavy substances, such as lead, brass, ivory, 
 &,c., be suspended by fine threads of equal length, they will 
 vibrate in the same time, provided their weights bear a con- 
 11* 
 
126 THE ELEMENTS OF MECHANICS. CHAP. XI 
 
 siderable proportion to the atmospherical resistance, or that 
 they be suspended in vacuo. 
 
 (211.) Since the time of vibration of a pendulum, which 
 oscillates in small arcs, depends neither on the magnitude 
 of the arc of vibration nor on the quality or weight of the 
 pendulous body, it will be necessary to explain the circum- 
 stances on which the variation of this time depends. 
 
 The first and most striking of these circumstances is the 
 length of the suspending thread. The rudest experiments 
 will demonstrate the fact, that every increase in the length of 
 this thread will produce a corresponding increase in the time 
 of vibration ; but according to what law does this increase pro- 
 ceed ? If the length of the thread be doubled or trebled, will 
 the time of vibration also be increased in a double or treble 
 proportion ? This problem is capable of exact mathematical 
 solution, and the result shows that the time of vibration in- 
 creases, not in the proportion of the increased length of the 
 thread, but as the square root of that length ; that is to say, 
 if the length of the thread be increased in a four-fold propor- 
 tion, the time of vibration will be augmented in a two-fold 
 proportion. If the thread be increased to nine times its 
 length, the time of vibration will be trebled, and so on. This 
 relation is exactly the same as that which was proved to sub- 
 sist between the spaces through which a body falls freely, 
 and the times of fall. In the table, page 75, if the figures 
 representing the height be understood to express the length 
 of different pendulums, the figures immediately above them 
 will express the corresponding times of vibration. 
 
 This law of the proportion of the lengths of pendulums to 
 the squares of the time of vibration may be experimentally 
 established in the following manner : 
 
 Let A, B, C, Jig. 74., be three small pieces of metal, each 
 attached by threads to two points of suspension, and let them 
 be placed in the same vertical line under the point O ; sup- 
 pose them so adjusted that the distances O A, OB, and O C, 
 .shall be in the proportion of the numbers 1, 4, and 9. Let 
 them be removed from the vertical in a direction at right 
 angles to the plane of the paper, so that the threads shall be 
 in the same plane, and therefore the three pendulums will 
 have the same angle of vibration. Being now liberated, the 
 pendulum A will immediately gain upon B, and B upon C, so 
 that A will have completed one vibration before Bor C. At the 
 

 CHAP. XI. THE PENDULUM. 127 
 
 end of the second vibration of A, the pendulum B will have 
 arrived at the end of its first vibration, so that the suspend- 
 ing threads of A and B will then be separated by the whole 
 angle of vibration ;' at the end of the fourth vibration of A, 
 the suspending threads of A and B will return to their first 
 position, B having completed two vibrations; thus the propor- 
 tion of the times of vibration of B and A will be 2 to 1, the 
 proportion of their lengths being 4 to 1. At the end of the 
 third vibration of A, C will have completed one vibration, 
 and the suspending strings will coincide in the position dis- 
 tant by the whole angle of vibration from their first position. 
 So that three vibrations of A are performed in the same time 
 as one of C : the proportion of the time of vibration of C and 
 A is, therefore, 3 to 1, the proportion of their lengths being 
 9 to 1, conformably to the law already explained. 
 
 ( 1:2.) [n all the preceding observations we have assumed 
 that the material of the pendulous body is of inconsiderable 
 magnitude, its whole weight being conceived to be collected 
 into a physical point. This is generally called a simple pen- 
 dulum ; but since the conditions of a suspending thread without 
 weight, and a heavy molecule without magnitude, cannot have 
 practical existence, the simple pendulum must be considered 
 as imaginary, and merely used to establish hypothetical theo- 
 rems, which, though inapplicable in practice, are nevertheless 
 the means of investigating the laws which govern the real 
 phenomena of pendulous bodies. 
 
 A pendulous body being of determinate magnitude, its 
 several parts will be situated at different distances from the 
 axis of suspension. If each component part of such a 
 body were separately connected with the axis of suspension 
 by a fine thread, it would, if unconnected with the other 
 particles, be an independent simple pendulum, and would 
 oscillate according to the laws already explained. It there- 
 fore follows that those particles of the body which are nearest 
 to the axis of suspension would, if liberated from their con- 
 nection with the others, vibrate more rapidly than those which 
 are more remote. The connection, however, which the par- 
 ticles of the body have, by reason of their solidity, compels 
 them all to vibrate in the same time. Consequently, those 
 particles which are nearest the axis are retarded by the slower 
 motion of those which are more remote ; while the more 
 remote particles, on the other hand, are urged forward by 
 the greater tendency of the nearer particles to rapid vibration 
 
128 THE ELEMENTS OF MECHANICS. CHAP. XI. 
 
 This will be more readily comprehended, if we conceive two 
 particles of matter, A and B, Jiff. 75., to be connected with 
 the same axis O by an inflexible wire O C, the weight of 
 which may be neglected. If B were removed, A would vi- 
 brate in a certain time depending upon the distance O A. 
 If A were removed, and B placed upon the wire at a distance 
 B O equal to four times A O, B would vibrate in twice the 
 former time. Now, if both be placed on the wire at the 
 distances just mentioned, the tendency of A to vibrate more 
 rapidly will be transmitted to B by means of the wire, and 
 will urge B forward more quickly than if A were not present: 
 on the other hand, the tendency of B to vibrate more slowly 
 will be transmitted by the wire to A, and will cause it to 
 move more slowly than if B were not present. The inflex- 
 ible quality of the connecting wire will in this case compel 
 A and B to vibrate simultaneously, the time of vibration be- 
 ing greater than that of A, and less than that of B, if each 
 vibrated unconnected with the other. 
 
 If, instead of supposing two particles of matter placed on 
 the wire, a greater number were supposed to be placed at 
 various distances from O, it is evident the same reasoning 
 would be applicable. They would mutually affect each other's 
 motion ; those placed nearest to point O accelerating the 
 motion of those more remote, and being themselves retarded 
 by the latter. Among these particles one would be found in 
 which all these effects would be mutually neutralized, all the 
 particles nearer O being retarded in reference to that motion 
 which they would have if unconnected with the rest, and 
 those more remote being in the same respect accelerated. 
 The point at which such a particle is placed is called the 
 centre of oscillation. 
 
 What has been here observed of the effects of particles 
 of matter placed upon rigid wire will be equally applicable to 
 the particles of a solid body. Those which are nearer to 
 the axis are urged forward by those which are more remote, 
 and are, in their turn, retarded by them ; and, as with the 
 particles placed upon the wire, there is a certain particle 
 of the body at which the effects are mutually neutralized, 
 and which vibrates in the same time as it would if it were 
 unconnected with the other parts of the body, and simply 
 connected by a fine thread to the axis. By this centre of 
 oscillation the calculations respecting the vibration of a solid 
 body are rendered as simple as those of a molecule of incon- 
 
CHAP. XI. CENTRE OF OSCILLATION. 129 
 
 siderable magnitude. All the properties which have been 
 explained as belonging to a simple pendulum may thus be 
 transferred to a vibrating body of any magnitude and figure, 
 by considering it as equivalent to a single particle of matter 
 vibrating at its centre of oscillation. 
 
 (213.) It follows from this reasoning, that the virtual length 
 of a pendulum is to be estimated by the distance of its centre 
 of oscillation from the axis of suspension, and therefore that 
 the times of .vibration of different pendulums are in the same 
 proportion as the square roots of the distances of their centres 
 of oscillation from their axes. 
 
 The investigation of the position of the centre of oscilla- 
 tion is, in most cases, a subject of intricate mathematical 
 calculation. It depends on the magnitude and figure of the 
 pendulous body, the manner in which the mass is distributed 
 through its volume, or the density of its several parts, and 
 the position of the axis on which it swings. 
 
 The place of the centre of oscillation may be determined 
 when the position of the centre of gravity and the centre of 
 gyration are known ; for the distance of the centre of oscilla- 
 tion from the axis will always be obtained by dividing the 
 square of the radius of gyration (180.) by the distance of the 
 centre of gravity from the axis. Thus, if 6 be the radius 
 of gyration, and 9 the distance of gravity from the axis, 36 
 divided by 9, which is 4, will be the distance of the centre 
 of oscillation from the axis. Hence it may be inferred gen 
 erally, that the greater the proportion which the radius of 
 gyration bears to the distance of the centre of gravity from 
 the axis, the greater will be the distance of the centre of os- 
 cillation. 
 
 It follows from this reasoning, that the length of a pen- 
 dulum is not limited by the dimensions of its volume. If the 
 axis be so placed that the centre of gravity is near it, and 
 the centre of gyration comparatively removed from it, the 
 centre of oscillation may be placed far beyond the limits of 
 the pendulous body. Suppose the centre of gravity is at a 
 distance of one inch from the axis, and the centre of gyra- 
 tion 12 inches, the centre of oscillation will then be at the 
 distance of 144 inches, or 12 feet. Such a pendulum may 
 not, in its greatest dimensions, exceed one foot, and yet its 
 time of vibration would be equal to that of a simple pendulum 
 whose length is 12 feet. 
 
 By these means pendulums of small dimensions may be 
 
130 T^IE ELEMENTS OF MECHANICS. CHAP. XI. 
 
 made to vibrate as slowly as may be desired. The instru- 
 ments called metronomes, used for marking the time of musical 
 performances, are constructed on this principle. 
 
 (214.) The centre of oscillation is distinguished by a very 
 remarkable property in relation to the axis of suspension. If 
 A, Jig- 76., be the point of suspension, and O the correspond- 
 ing centre of oscillation, the time of vibration of the pendu- 
 lum will not be changed if it be raised from its support, 
 inverted, and suspended from the point O. It follows, there- 
 fore, that if O be taken as the point of suspension, A will 
 be the corresponding centre of oscillation. These two points 
 are, therefore, convertible. This property may be verified 
 experimentally in the following manner. A pendulum being 
 put into a state of vibration, let a small heavy body be sus- 
 pended by a fine thread, the length of which is so adjusted 
 that it vibrates simultaneously with the pendulum. Let the 
 distance from the point of suspension to the centre of the 
 vibrating body be measured, and take this distance on the 
 pendulum from the axis of suspension downwards ; the place 
 of the centre of oscillation will thus be obtained, since the 
 distance so measured from the axis is the length of the equiv- 
 alent simple pendulum. If the pendulum be now raised 
 from its support, inverted, and suspended from the centre 
 of oscillation thus obtained, it will be found to vibrate simul- 
 taneously with the body suspended by the thread. 
 
 (215.) This property of the interchangeable nature of the 
 centres of oscillation and suspension has been, at a late 
 period, adopted by Captain Kater, as an accurate means of 
 determining the length of a pendulum. Having ascertained 
 with great accuracy two points of suspension at which the 
 same body will vibrate in the same time, the distance be- 
 tween these points, being accurately measured, is the length 
 of the equivalent simple pendulum. Se Chapter XXI. 
 
 (216.) The manner in which the time of vibration of a 
 pendulum depends on its length being explained, we are 
 next to consider how this time is affected by the attraction 
 of gravity. It is obvious that, since the pendulum is moved 
 by this attraction, the rapidity of its motion will be increased, 
 if the impelling force receives any augmentation ; but it still 
 is to be decided, in what exact proportion the time of oscilla- 
 tion will be diminished by any proposed increase in the in- 
 tensity of the earth's attraction. It can be demonstrated 
 mathematically, that the time of one vibration of a pendulum 
 
CHAP* XI. TIME OF VIBRATION. 131 
 
 has the same proportion to the time of falling freely in the 
 perpendicular direction, through a height equal to half the 
 length of the pendulum, as the circumference of a circle has 
 to its diameter. Since, therefore, the times of vibration of 
 pendulums are in a fixed proportion to the times of falling 
 freely through spaces equal to the halves of their lengths, it 
 follows that these times have the same relation to the force 
 of attraction as the times of falling freely through their 
 lengths have to that force. If the intensity of the force of 
 gravity were increased in a four-fold proportion, the time of 
 falling through a given height would be diminished in a two- 
 fold proportion ; if the intensity were increased to a nine-fold 
 proportion, the time of falling through a given space would 
 be diminished in a three-fold proportion, and so on ; the rate 
 of diminution of the time being always as the square root 
 of the increased force. By what has been just stated, this 
 law will also be applicable to the vibration of pendulums. 
 Any increase in the intensity of the force of gravity would 
 cause a given pendulum to vibrate more rapidly, and the in- 
 creased rapidity of the vibration would be in the same pro- 
 portion as the square root of the increased intensity of the 
 force of gravity. 
 
 (217.) The laws which regulate the times of vibration of 
 pendulums in relation to one another being well understood, 
 the whole theory of these instruments will be completed, 
 when the method of ascertaining the actual time of vibration 
 of any pendulum, in reference to its length, has been explain- 
 ed. In such an investigation, the two elements to be deter- 
 mined are, 1. the exact time of a single vibration, and, 2. the 
 exact distance of the centre of oscillation from the point of 
 suspension. 
 
 The former is ascertained by putting a pendulum in motion 
 in the presence of a good chronometer, and observing pre- 
 cisely the number of oscillations which are made in any pro- 
 posed number of hours. The entire time during which the 
 pendulum swings, being divided by the number of oscillations 
 made during that time, the exact time of one oscillation will 
 be obtained. 
 
 The distance of the centre of oscillation from the point 
 of suspension may be rendered a matter of easy calculation, 
 by giving a certain uniform figure and material to the pendu- 
 lous body. 
 
 (218.) The time of vibration of one pendulum of known 
 
' 
 132 THE ELEMENTS OF MECHANICS. CHAP. XI. 
 
 length being thus obtained, we shall be enabled immediately 
 to solve either of the following problems. 
 
 " To find the length of a pendulum which shall vibrate in 
 a given time." 
 
 " To find the time of vibration of a pendulum of a given 
 length." 
 
 The former is solved as follows : the time of vibration of 
 the known pendulum is to the time of vibration of the requir- 
 ed pendulum as the square root of the length of the known 
 pendulum is to the square root of the length of 'the required 
 pendulum. This length is therefore found by the ordinary 
 rules of arithmetic. 
 
 The latter may be solved as follows : the length of the 
 known pendulum is to the length of the proposed pendulum, 
 as the square of the time of vibration of the known pendu- 
 lum is to the square of the time of vibration of the proposed 
 pendulum. The latter time may therefore be found by arith- 
 metic. 
 
 (219.) Since the rate of a pendulum has a known relation 
 to the intensity of the earth's attraction, we are enabled, 
 by this instrument, not only to detect certain variations in 
 that attraction in various parts of the earth, but also to 
 discover the actual amount of the attraction at any given 
 place. 
 
 The actual amount of the earth's attraction at any given 
 place is estimated by the height through which a body would 
 fall freely at that place in any given time, as in one second. 
 To determine this, let the length of a pendulum which would 
 vibrate in one second at that place be found. As the circum- 
 ference of a circle is to its diameter (a known proportion), so 
 will one second be to the time of falling through a height 
 equal to half the length of this pendulum. This time is 
 therefore a matter of arithmetical calculation. It has been 
 proved in (120.), that the heights, through which a body falls 
 freely, are in the same proportion as the squares of the times ; 
 from whence it follows, that the square of the time of falling 
 through a height equal to half the length of the pendulum is 
 to one second as half the length of that pendulum is to the 
 height through which a body would fall in one second. This 
 height, therefore, may be immediately computed, and thus 
 the actual amount of the force of gravity at any given place 
 may be ascertained. 
 
 (220.) To compare the force of gravity in different parts 
 
CHAP. XI. VARIATION OP GRAVITY. 133 
 
 of the earth, it is only necessary to swing the same pendu- 
 lum in the places under consideration, and to observe the 
 rapidity of its vibrations. The proportion of the force of 
 gravity in the several places will be that of the squares of the 
 velocity of the vibration. Observations to this effect have 
 been made at several places, by Biot, Kater, Sabine and 
 others. 
 
 The earth being a mass of matter of a form nearly spher- 
 ical, revolving with considerable velocity on an axis, its 
 component parts are affected by a centrifugal force ; in virtue 
 of which, they have a tendency to fly off in a direction per- 
 pendicular to the axis. This tendency increases in the same 
 proportion as the distance of any part from the axis increases, 
 and consequently those parts of the earth which are near the 
 equator, are more strongly affected by this influence than 
 those near the pole. It has been already explained (145) that 
 the figure of the earth is affected by this cause, and that it 
 has acquired a spheroidal form. The centrifugal force, acting 
 in opposition to the earth's attraction, diminishes its effects ; 
 and, consequently, where this fprce is more efficient, a pendu- 
 lum will vibrate more slowly. By these means the rate of 
 vibration of a pendulum becomes an indication of the amount 
 of the centrifugal force. But this latter varies in proportion 
 to the distance of the place from the earth's axis ; and thus 
 the rate of a pendulum indicates the relation of the distances 
 of different parts of the earth's surface from its axis. The 
 figure of the earth may be thus ascertained, and that which 
 theory assigns to it, it may be practically proved to have. 
 
 This, however, is not the only method by which the figure 
 of the earth may be determined. The meridians being sec- 
 tions of the earth through its axis, if their figure were exactly 
 determined, that of the earth would be known. Measure- 
 ments of arcs of meridians, on a large scale have been exe- 
 cuted, and are still being made in various parts of the earth, 
 with a view to determine the curvature of a meridian at dif- 
 ferent latitudes. This method is independent of every hy- 
 pothesis concerning the density and internal structure of the 
 earth, and is considered by some to be susceptible of more 
 accuracy than that which depends on the observations of 
 pendulums. 
 
 (221.) It has been stated that, when the arc of vibration 
 of a pendulum is not very small, a variation in its length will 
 produce a sensible effect on the time of vibration. To con- 
 12 
 
THE ELEMENTS OF MECHANICS. CHAP. XI. 
 
 struct a pendulum such that the time of vibration may be 
 independent of the extent of the swing, was a favorite spec- 
 ulation of geometers. This problem was solved by Huygens, 
 who showed that the curve called a cycloid, previously dis- 
 covered and described by Galileo, possessed the isochronal 
 property ; that is, that a body moving in it by the force of 
 gravity would vibrate in the same time, whatever be the 
 length of the arc described. 
 
 Let O A,f,g. 77., be a horizontal line, and let O B be a 
 circle placed below this line, and in contact with it. If this 
 circle be rolled upon the line from O towards A, a point 
 upon its circumference, which, at the beginning of the 
 motion, is placed at O, will, during the motion, trace the 
 curve OCA. This curve is called a cycloid. If the circle 
 be supposed to roll in the opposite direction towards A', the 
 same point will trace another cycloid O C' A'. The points 
 C and C' being the lowest points of the curves, if the per- 
 pendiculars C D and C' D' be drawn, they will respectively 
 be equal to the diameter of the circle. By a known property 
 of this curve, the arcs O C and O C' are equal to twice the 
 diameter of the circle. From the point O suppose a flexible 
 thread to be suspended, whose length is twice the diameter 
 of the circle, and which sustains a pendulous body P at its 
 extremity. If the curves O G and O C', from the plane of 
 the paper, be raised so as to form surfaces to which the thread 
 may be applied, the extremity P will extend to the points C 
 and C', when the entire thread has been applied to either of 
 the curves. As the thread is deflected on either side of its 
 vertical position, it is applied to a greater or lesser portion of 
 either curve, according to the quantity of its deflection 
 from the vertical. If it be deflected on each side until 
 the point P reaches the points C and C', the extremity would 
 trace a cycloid C P C' precisely equal and similar to those 
 already mentioned. Availing himself of this property of the 
 curve, Huygens constructed his cycloid al pendulum. The 
 time of vibration was subject to no variation, however the 
 arc of vibration might change, provided only that the length 
 of the string O P continued the same. If small arcs of the 
 cycloid be taken on either side of the point P, they will 
 not sensibly differ from arcs of a circle described with 
 the centre O and the radius O P ; for, in slight deflections 
 from the vertical position, the effect of the curves O C and 
 O C' on the thread O P is altogether inconsiderable. It is 
 
CHAP. XII. SIMPLE MACHINES. 135 
 
 for this reason that, when the arcs of vibration of a circular 
 pendulum are small, they partake of the property of isochro- 
 nism peculiar to those of a cycloid. But when the deflection 
 of P from the vertical is great, the effect of the curves O C 
 and O C' on the thread produces a considerable deviation of 
 the point P from the arc of the circle whose centre is O and 
 whose radius is O P, and consequently the property of 
 isochronism will no longer be observed in the circular 
 pendulum 
 
 CHAPTER XII. 
 
 OF SIMPLE MACHINES. 
 
 (222.) A MACHINE is an instrument by which force or mo- 
 tion may be transmitted and modified as to its quantity and 
 direction. There are two ways in which a machine may be 
 applied, and which give rise to a division of mechanical sci- 
 ence into parts denominated STATICS and DYNAMICS ; the 
 one including the theory of equilibrium, and the other the 
 theory of motion. When a machine is considered statically, 
 it is viewed as an instrument by which forces of determinate 
 quantities and directions are made to balance other forces 
 of other quantities and other directions. If it be viewed 
 dynamically, it is considered as a means by which certain 
 motions of determinate quantity and direction may be made 
 to produce other motions in other directions and quantities. 
 It will not be convenient, however, in the present treatise, 
 to follow this division of the subject. We shall, on the other 
 hand, as hitherto, consider the phenomena of equilibrium 
 and motion together. 
 
 The effects of machinery are too frequently described in 
 such a manner as to invest them with the appearance of par- 
 adox, and to excite astonishment at what appears to contra- 
 dict the results of the most common experience. It will be 
 our object here to take a different course, and to attempt to 
 show that those effects which have been held up as matters 
 of astonishment are the necessary, natural and obvious re- 
 sults of causes adapted to produce them in a manner analo- 
 gous to the objects of most familiar experience. 
 
 (223.) In the application of a machine the^e are three 
 
136 THE ELEMENTS OF MECHANICS. CHAP. XII. 
 
 things to be considered. t> The force or resistance which 
 is required to be sustained, opposed, or overcome. 2. The 
 force which is used to sustain, support, or overcome that re- 
 sistance. 3. The machine itself, by which the effect of this 
 latter force is transmitted to the former. Of whatever nature 
 be the force or the resistance which is to be sustained or 
 overcome, it is technically called the weight^ since, whatever 
 it be, a weight of equivalent effect may always be found. 
 The force which is employed to sustain or overcome it is 
 technically called the power. 
 
 (224.) In expressing the effect of machinery, it is usual to 
 say that the power sustains the weight ; but this, in fact, is 
 not the case, and hence arises that appearance of paradox 
 which has already been alluded to. If, for example, it is said 
 that a power of one ounce sustains the weight of one ton, 
 astonishment is not unnaturally excited, because the fact, as 
 thus stated, if the terms be literally interpreted, is physically 
 impossible. No power less than a ton can, in the ordinary 
 acceptation of the word, support the weight of a ton. It will, 
 however, be asked how it happens that a machine appears to 
 do this? how it happens that by holding a silken thread, 
 which an ounce weight would snap, many hundred weight 
 may be sustained ? To explain this, it will only be necessary 
 to consider the effect of a machine, when the power and 
 Weight are in equilibrium. 
 
 (225.) In every machine there are some fixed points or 
 props; and the arrangement of the parts is always such, that 
 the pressure, excited by the power or weight, or both, is dis- 
 tributed among these props. If the weight amoumt to twenty 
 hundred, it is possible so to distribute it, that any proportion, 
 however great, of it may be thrown on the fixed points or 
 props of the machine ; the remaining part only can properly 
 be said to be supported by the power ; and this part can never 
 be greater than the power. Considering the effect in this 
 way, it appears that the power supports just so much of the 
 weight, and no more, as is equal to its own force, and that all 
 the remaining part of the weight is sustained by the machine. 
 
 The force of these observations will be more apparent 
 when the nature and properties of the mechanic powers and 
 other machines have been explained. 
 
 (226.) When a machine is used dynamically /its effects are 
 explained on different principles. It is true that, in this case, 
 a very small power may elevate a very great weight; but, 
 
CHA^. XII. SIMPLE MACHINES. 137 
 
 nevertheless, in so doing, whatever be the machine used, the 
 total expenditure of power, in raising the weight through any 
 height, is never less than that which would be expended if 
 the power were immediately applied to the weight without the 
 intervention of any machine. This circumstance arises from 
 an universal property of machines, by which the velocity of 
 the weight is always less than that of the power, in exactly 
 the same proportion as the power itself is less than the weight ; 
 so that, when a certain power is applied to elevate a weight, 
 the rate at which the elevation is effecte^l is always slow in 
 the same proportion as the weight is great. From a due con- 
 sideration of this remarkable law, it will easily be understood 
 that a machine can never diminish the total expenditure of 
 power necessary to raise any weight or to overcome any re- 
 sistance. In such cases, all that a machine ever does, or ever 
 can do, is to enable the power to be expended at a slow rate, 
 and in a more advantageous direction than if it were immedi- 
 ately applied to the weight or the resistance. 
 
 Let us suppose that P is a power amounting to an ounce, 
 and that W is a weight amounting to 50 ounces, and that P 
 elevates W by means of a machine. In virtue of the prop- 
 erty already stated, it follows, that while P moves through 50 
 feet, W will be moved through 1 foot ; but in moving P through 
 50 feet, 50 distinct efforts are made, by each of which 1 ounce 
 is moved through 1 foot, and by which collectively 50 distinct 
 ounces might be successively raised through 1 foot But 
 the weight W is 50 ounces, and has been raised through 1 
 foot ; from whence it appears, that the expenditure of power 
 is equal to that which would be necessary to raise the weight 
 without the intervention of any machine. 
 
 This important principle may _be presented under another 
 aspect, which will perhaps render it more apparent. Suppose 
 t pi weight W were actually divided into 50 equal parts, or 
 .suppose it were a vessel of liquid weighing 50 ounces, and 
 containing 50 equal measures; if these 50 measures' were 
 successively lifted through a height of 1 foot, the efforts neces- 
 sary to accomplish this would be the same as tjhose used to 
 move the power P through 50 feet, and it is obv ious, that the 
 total expenditure of force would be the same as that which 
 would be necessary to lift the entire contents of the vessel 
 through 1 foot. 
 
 When the nature and properties of the mechanic powers 
 
 and other machines have been explained, the ji>rce t?f these 
 
 12* 
 
138 THE ELEMENTS OF MECHANICS. CHAP. XII. 
 
 observations will be more distinctly perceived, The effects 
 of props and fixed points in sustaining a part of the weight, 
 and sometimes the whole, both of the weight and power, will 
 then be manifest, and every machine will furnish a verifica- 
 tion of the remarkable proportion between the velocities of 
 the weight and power, which has enabled us to explain what 
 might otherwise be paradoxical and difficult of comprehen- 
 sion. 
 
 (227.) The most simple species of machines are those 
 which are commonly denominated the MECHANIC POWERS. 
 These have been differently enumerated by different writers. 
 If, however, the object be to arrange in distinct classes, and 
 in the smallest possible number of them, those machines 
 which are alike in principle, the mechanic powers may be 
 reduced to three. 
 
 1. The lever. 
 
 2. The cord. 
 
 3. The inclined plane 
 
 To one or other of these classes all simple machines what- 
 ever may be reduced, and all complex machines may be re- 
 solvefl into simple elements which come under them. 
 
 (228.) The first class includes every machine which is 
 composed of a solid body revolving on a fixed axis, although 
 the name lever has been commonly confined to cases where 
 the machine affects certain particular forms. This is by far 
 the most useful class of machines, and will require, in subse- 
 quent chapters, very detailed developement. The general 
 principle, uj>on which equilibrium is established between 
 the power and weight in machines of this class has been 
 already explained in (183.) The power and weight are 
 always supposed to be applied in directions at right angles to 
 the axis. If lines be drawn from the axis perpendicular I* 
 the direction* of power and weight, equilibrium will subsist, 
 provided the power multiplied by the perpendicular distance 
 of its direction from the axis, be equal to the weight multi- 
 plied by the perpendicular distance of its direction from the 
 axis. This is a principle to which we shall have occasion to 
 refer in explaining the various machines of this class. 
 
 (229.) If the moment of the power (KS4.) be greater than 
 that of the weight, the effect of the power will prevail over 
 that of the weight, and elevate it; but if, on the other hand, 
 the moment of the uower be less than that of the weight, the 
 
CHAP, XII. SIMPLE MACHINES. 139 
 
 power will be insufficient to support the weight, and will allow 
 it to fall. 
 
 (230.) The second class of simple machines includes all 
 those cases in which force is transmitted by means of flexible 
 threads, ropes, or chains. The principle, by which the effects 
 of these machines are estimated, is, that the tension through- 
 out the whole length of the same cord, provided it be perfect- 
 ly flexible, and free from the effects of friction, must be the 
 same. Thus, if a force acting at one end be balanced by a 
 force acting at the other end, however the cord may be bent, 
 or whatever course it may be compelled to take, by any causes 
 which may affect it between its ends, these forces must be 
 equal, provided the cord be free to move over any obstacles 
 which may deflect it. 
 
 Within this class of machines are included all the various 
 forms of pit/leys. 
 
 (231.) The third class of simple machines includes all 
 those cases in which the weight or resistance is supported 
 or moved on a hard surface inclined to the vertical direction. 
 
 The effects of such machines are estimated by resolving 
 the whole weight of the body into two elements by the paral- 
 lelogram of forces. One of these elements is perpendicular 
 to the surface, and supported by its resistance ; the other is 
 parallel to the surface, and supported by the power. The 
 proportion, therefore, of the power to the weight will always 
 depend on the obliquity of the surface to the direction of the 
 weight. This will be easily understood by referring to what 
 has been already explained in Chapter VJlI. 
 
 Under this class of machines, come the inclined plane, 
 commonly so called, the wedge, the screw, and various 
 others. 
 
 (232.) In order to simplify the developement of the ele- 
 mentary theory of machines, it is expedient to omit the con- 
 sideration of many circumstances, of which, however, a strict 
 account must be taken before any practically useful applica- 
 tion of that theory can be attempted. A machine, as we 
 must for the present contemplate it, is a thing which can have 
 no real or practical existence. Its various parts are considered 
 to be free from friction : all surfaces which move in contact 
 are supposed to be infinitely smooth and polished. The solid 
 parts are conceived to be absolutely inflexible. The weight 
 and inertia of the machine itself are wholly neglected, arid 
 we reason upon it as if it were divested of these qualities. 
 
140 THE ELEMENTS OF MECHANICS. CHAP. XII. 
 
 Cords and ropes are supposed to have no stiffness, to be infi- 
 nitely flexible. The machine, when it moves, is supposed to 
 suffer no resistance from the atmosphere, and to be in all re- 
 spects circumstanced as if it were'm vacua. 
 
 It is scarcely necessary to state, that, all these suppositions 
 being false, none of the consequences deduced from them can 
 be true. Nevertheless, as it is the business of art to bring 
 machines as near to this state of ideal perfection as possible, 
 the conclusions which are thus obtained, though false in a 
 strict sense, yet deviate from the truth in but a small degree. 
 Like the first outline of a picture, they resemble, in their gen- 
 eral features, that truth to which, after many subsequent cor- 
 rections, they must finally approximate. 
 
 After a first approximation has been made on the several 
 false suppositions which have been mentioned, various effects, 
 which have been previously neglected, are successively taken 
 into account. Roughness, rigidity, imperfect flexibility, the 
 resistance of air and other fluids, the effects of the weight 
 and inertia of the machine, are severally examined, and their 
 laws and properties detected. The modifications and correc- 
 tions, thus suggested as necessary to be introduced into our 
 former conclusions, are applied, and a second approximation, 
 but still only an approximation, to truth is made. For, in in- 
 vestigating the laws which regulate the several effects just 
 mentioned, we are compelled to proceed upon a new group 
 of false suppositions. To determine the laws which regulate 
 the friction of surfaces, it is necessary to assume that every 
 part of the surfaces of contact is uniformly rough ; that the 
 solid parts which are imperfectly rigid, and the cords which 
 are imperfectly flexible, are constituted throughout their entire 
 dimensions of a uniform material ; so that the imperfection 
 does not prevail more in one part than another. Thus all ir- 
 regularity is left out of account, and a general average of the 
 effects taken. It is obvious, therefore, that by these means 
 we have still failed in obtaining a result exactly conformable 
 to the real state of things ; but it is equally obvious that we 
 have obtained one much more conformable to that state than 
 had been previously accomplished, and sufficiently near it for 
 most practical purposes. 
 
 This apparent imperfection in our instruments and powers 
 of investigation is not peculiar to mechanics : it pervades all 
 departments of natural science. In astronomy, the motions 
 of the celestial bodies, and their various changes and appear 
 
CHAP. XIII. THE LEVER. 141 
 
 ances, as developed by theory, assisted by observation and 
 experience, are only approximations to the real motions and 
 appearances which take place in nature. It is true that these 
 approximations are susceptible of almost unlimited accuracy ; 
 but still they are, and ever will continue to be, only approxi- 
 mations. Optics and all other branches of natural science 
 are liable to the same observations. 
 
 CHAPTER XIII. 
 
 OF THE LEVER. 
 
 (233.) AN inflexible, straight bar, turning on an axis, is 
 commonly called a lever. The arms of the lever are those 
 parts of the bar which extend on each side of the axis. 
 
 The axis is called thejalcrum or prop. 
 
 (234.) Levers are commonly divided into three kinds, ac- 
 cording to the relative positions of the power, the weight and 
 the fulcrum. 
 
 In a lever of the first kind, as in Jig. 78., the fulcrum is be- 
 tween the power and weight. 
 
 In a lever of the second kind, as in Jig. 79., the weight is 
 between the fulcrum and power. 
 
 In a lever of the third kind, as in Jig. 80., the power is be- 
 tween the fulcrum and weight. 
 
 (235.) In all these cases, the power will sustain the weight 
 in equilibrium, provided its moment be equal to that of the 
 weight. (184.) But the moment of the power is, in this case, 
 equal to the product obtained by multiplying the power by its 
 distance from the fulcrum, and the moment of the weight, 
 by multiplying the weight by its distance from the fulcrum. 
 Thus, if the number of ounces in P, being multiplied by the 
 number of inches in P F, be equal to the number of ounces 
 in W, multiplied by the number of inches in W F, equilibrium 
 will be established. It is evident from this, that as the dis- 
 tance of the power from the fulcrum increases in comparison 
 to the distance of the weight from the fulcrum, in the same 
 degree exactly will the proportion of the power to the weight 
 diminish. In other words, the proportion of the power to the 
 weight will be always the same as that of their distances from 
 the fulcrum taken in a reverse order. 
 
142 THE ELEMENTS OF MECHANICS. CHAP. XIII 
 
 In cases where a small power is required to sustain or ele- 
 vate a great weight, it will therefore be necessary either to 
 remove the power to a great distance from the fulcrum, or to 
 bring the weight very near it. 
 
 (236.) Numerous examples of levers of the first kind may 
 be given. A crow-bar, applied to elevate a stone or other 
 weight, is an instance. The fulcrum is another stone placed 
 near that which is to be raised, and the power is the hand 
 placed at the other end of the bar. 
 
 A handspike is a similar example. 
 
 A poker applied to raise fuel is a lever of the first kind, 
 the fulcrum being the bar of the grate. 
 
 Scissors, shears, nippers, pincers, and other similar instru- 
 ments, are composed of two levers of the first kind ; the ful- 
 crum being the joint or pivot, and the weight the resistance 
 of the substance to be cut or seized ; the power being the 
 fingers applied at the other end of the levers. 
 
 The brake of a pump is a lever of the first kind ; the pump- 
 rods and piston being the weight to be raised. 
 
 (237.) Examples of levers of the second kind, though not 
 so frequent as those just mentioned, are not uncommon. 
 
 An oar is a lever of the second kind. The reaction of 
 the water against the blade is the fulcrum. The boat is the 
 weight, and the hand of the boatman the power. 
 
 The rudder of a ship or boat is an example of this kind of 
 lever, and explained in a similar way. 
 
 The chipping knife is a lever of the second kind. The 
 end attached to the bench is the fulcrum, and the weight the 
 resistance of the substance to be cut, placed beneath it. 
 
 A door moved upon its hinges is another example. 
 
 Nut-crackers are two levers of the second kind ; the hinge 
 which unites them being the fulcrum, the resistance of the 
 shell placed between them being the weight, and the hand 
 applied to the extremity being the power. 
 
 A wheelbarrow is a lever of the second kind ; the fulcrum 
 being the point at which the wheel presses on the ground, 
 arid the weight being that of the barrow and its load, collect- 
 ed at their centre of gravity. 
 
 The same observation may be applied to all two-wheeled 
 carriages, which are partly sustained by the animal which 
 draws them. 
 
 (238.) In a lever of the third kind, the weight, being 
 more distant from the fulcrum than the power, must be pro- 
 
CHAP. XIII. LEVERS. 143 
 
 portionably less than it. In this instrument, therefore, the 
 power acts upon the weight to a mechanical disadvantage, 
 inasmuch as a greater power is necessary to support or move 
 the weight than would be required if the power were imme- 
 diately applied to the weight, without the intervention of a 
 machine. We shall, however, hereafter show that the advan- 
 tage which is lost in force is gained in despatch, and that 
 in proportion as the weight is less than the power which moves 
 it, so will the speed of its motion be greater than that of the 
 power. 
 
 Hence a lever of the third kind is only used in cases 
 where the exertion of great power is a consideration subordi- 
 nate to those of rapidity and despatch. 
 
 The most striking example of levers of the third kind is 
 found in the animal economy. The limbs of animals are 
 generally levers of this description. The socket of the bone 
 is the fulcrum ; a strong muscle attached to the bone near 
 the socket is the power ; and the weight of the limb, together 
 with whatever resistance is opposed to its motion, is the 
 weight. A slight contraction of the muscle in this case 
 gives a considerable motion to the limb : this effect is par- 
 ticularly conspicuous in the motion of the arms and legs 
 in the human body ; a very inconsiderable contraction of 
 the muscles at the shoulders and hips giving the sweep to 
 the limbs from which the body derives so much activity. 
 
 The treddle of the turning lathe is a lever of the third 
 kind. The hinge which attaches it to the floor is the ful- 
 crum, the foot applied to it near the hinge is the power, and 
 the crank upon the axis of the fly-wheel, with which its ex- 
 tremity is connected, is the weight. 
 
 Tongs are levers of this kind, as also the shears used in 
 shearing sheep. In these cases, the power is the hand placed 
 immediately below the fulcrum, or point where the two levers 
 are connected. 
 
 (239.) When the power is said to support the weight by 
 means of a lever, or any other machine, it is only meant that 
 the power keeps the machine in equilibrium, and thereby 
 enables it to sustain the weight. It is necessary to attend 
 to this distinction, to remove the difficulty which may arise 
 from the paradox of a small power sustaining a great weight. 
 
 In a lever of the first kind, the fulcrum F, Jig. 78., or 
 axis, sustains the united forces of the power and weight. 
 
 In a lever of the second kind, if the power be supposed to 
 
144 THE ELEMENTS OF MECHANICS. CHAP. XIII. 
 
 act over a wheel R, fig. 79., the fulcrum F sustains a pres- 
 sure equal to the difference between the power and weight, 
 and the axis of the wheel R sustains a pressure equal to 
 twice the power ; so that the total pressures on F and R are 
 equivalent to the united forces of the power and weight. 
 
 In a lever of the third kind similar observations are appli- 
 cable. The wheel R, jig. 80., sustains a pressure equal to 
 twice the power, and the fulcrum F sustains a pressure equal 
 to the difference between the power and weight. 
 
 These facts may be experimentally established by attach- 
 ing a string to the lever immediately over the fulcrum, and 
 suspending the lever by that string from the arm of a balance. 
 The counterpoising weight, when the fulcrum is removed, 
 will, in the first case, be equal to the sum of the weight 
 and power, and in the last two cases equal to their differ- 
 ence. 
 
 (240.) We have hitherto omitted the consideration of the 
 effect of the weight of the lever itself. If the centre of 
 gravity of the lever be in the vertical line through the axis, 
 the weight of the instrument will have no other effect than 
 to increase the pressure on the axis by its own amount. But 
 if the centre of gravity be on the same side of the axis with 
 the weight, as at G, it will oppose the effect of the power, 
 a certain part of which must therefore be allowed to support 
 it. To ascertain what part of the power is thus expended, 
 it is to be considered that the moment of the weight of the 
 lever collected at G, is found by multiplying that weight by 
 the distance G F. The moment of that part of the power 
 which supports this must be equal to it ; therefore, it is only 
 necessary to find how much of the power multiplied by P F 
 will be equal to the weight of the lever multiplied by G F. 
 This is a question in common arithmetic. 
 
 If the centre of gravity of the lever be at a different side 
 of the axis from the weight, as at G',the weight of the instru- 
 ment will co-operate with the power in sustaining the weight 
 W. To determine what portion of the weight W is thus 
 sustained by the weight of the lever, it is only necessary to 
 find how much of W, multiplied by the distance W F, is 
 equal to the weight of the lever multiplied by G' F. 
 
 In these cases, the pressure on the fulcrum, as already 
 estimated, will always be increased by the weight of the 
 Jever. 
 
 (241.) The sense in which a small power is said to sustain 
 
CHAP. XIII. LEVERS. 145 
 
 a great weight, and the manner of accomplishing this, being 
 explained, we shall now consider how the power is applied 
 in moving the weight. Let P W, Jig. 81., be the places 
 of the power and weight, and F that of the fulcrum, and let 
 the power be depressed to P' while the weight is raised to 
 W. The space P P' evidently bears the same proportion to 
 W W', as the arm P F to W F. Thus, if P F be ten times 
 W F, P P' will be ten times W W'. A power of one pound 
 at P being moved from P to P 7 , will carry a weight of ten 
 pounds from W to W. But in this case it ought not to be 
 said, that a lesser weight moves a greater, for it is not diffi- 
 cult to show that the total expenditure of force in the motion 
 of one pound from P to P 7 is exactly the same as in the mo- 
 tion of ten pounds from W to W 7 - If the space P P 7 be ten 
 inches, the space W W 7 will be one inch. A weight of one 
 pound is therefore moved through ten successive inches, and 
 in each inch the force expended is that which would be suffi- 
 cient to move one pound through one inch. The total expen- 
 diture of force from P to P 7 is ten times the force necessary 
 to move one pound through one inch, or, what is the same, 
 it is that which would be necessary to move ten pounds through 
 one inch. But this is exactly what is accomplished by the 
 opposite end W of the lever ; for the weight W is ten pounds, 
 and the space W W is one inch. 
 
 If the \veight W of ten pounds could be conveniently di- 
 vided into ten equal parts of one pound each, each part might 
 be separately raised through one inch, without the interven- 
 tion of the lever or any other machine. In this case, the 
 same quantity of power would be expended, and expended in 
 the same manner as in the case just mentioned. 
 
 It is evident, therefore, that when a machine is applied to 
 raise a weight or to overcome resistance, as much force must 
 be really used as if the power were immediately applied to 
 the weight or resistance. All that is accomplished by the 
 machine is to enable the power to do that by a succession 
 of distinct efforts which should be otherwise performed by a 
 single effort. These observations will be found to be appli- 
 cable to all other machines. 
 
 (242.) Weighing machines of almost every kind, whether 
 used for commercial or philosophical purposes, are varieties 
 of the lever. The common balance, which, of all weighing 
 machines, is the most perfect, and best adapted for ordinary 
 use whether in commerce or experimental philosophy, is a 
 13 
 
146 THE ELEMENTS OF MECHANICS. CHAP. XIII. 
 
 lever with equal arms. In the steel-yard, one weight serves 
 as a counterpoise and measure of others of different amount, 
 by receiving a leverage variable according to the varying 
 amount of the weight against which it acts. A detailed 
 account of such instruments will be found in Chapter XXI. 
 
 (243.) We have hitherto considered the power and weight 
 as acting on the lever, in directions perpendicular to its 
 length, and parallel to each other. This does not always 
 happen. Let A B, Jig. 83., be a lever whose fulcrum is F, 
 and let A R be the direction of the power, and B S the 
 direction of the weight. If the lines R A and S B be con- 
 tinued, and perpendiculars F C and F D drawn from the 
 fulcrum to those lines, the moment of the power will be found 
 by multiplying the power by the line F C, and the moment 
 of the weight by multiplying the weight by F D. If these 
 moments be equal, the power will sustain the weight in equi- 
 librium. (185.) 
 
 It is evident that the same reasoning will be applicable 
 when the arms of the lever are not in the same direction. 
 These arms may be of any figure or shape, and may be placed 
 relatively to each other in any position. 
 
 (244.) In the rectangular lever the arms are perpendicular 
 to each other, and the fulcrum F, Jig. 84., is at the right 
 angle. The moment of the power, in this case, is P multi- 
 plied by A F, and that of the weight W multiplied by B F. 
 When the instrument is in equilibrium these moments must 
 be equal. 
 
 When the hammer is used for drawing a nail, it is a lever 
 of this kind : the claw of the hammer is the shorter arm ; 
 the resistance of the nail is the weight ; and the hand ap- 
 plied to the handle the power. 
 
 (245.) When a beam rests on two props A B, Jig. 85., 
 and supports, at some intermediate place C, a weight W, 
 this weight is distributed between the props in a manner 
 which may be determined by the principles already explained. 
 If the pressure on the prop B be considered as a power sus- 
 taining the weight W, by means of the lever of the second 
 kind B A, then this power multiplied by B A must be equal 
 to the weight multiplied by C A. Hence the pressure on B 
 will be the same fraction of the weight as the part A C is 
 of A B. In the same manner it may be proved, that the 
 pressure on A is the same fraction of the weight as B C is 
 of B A. Thus, if A C be one third, and therefore B C two 
 
CHAP. XIII. COMPOUND LEVERS. 147 
 
 thirds of B A, the pressure on B will be one third of the 
 weight, and the pressure on A two thirds of the weight. 
 
 It follows from this reasoning, that if the weight be in the 
 middle, equally distant from B and A, each prop will sustain 
 half the weight. The effect of the weight of the beam itself 
 may be determined by considering it to be collected at its 
 centre of gravity. If this point, therefore, be equally distant 
 from the props, the weight of the beam will be equally dis- 
 tributed between them. 
 
 According to these principles, the manner in which a load 
 borne on poles between two bearers is distributed between 
 them may be ascertained. As the efforts of the bearers and 
 th direction of the weight are always parallel, the position 
 of the poles relatively to the horizon makes no difference in 
 the distribution of the weights between the bearers. Whether 
 they ascend or descend, or move on a level plane, the weight 
 will be similarly shared between them. 
 
 If the beam extend beyond the prop, as in Jig. 86., and 
 the weight be suspended at a point not placed between 
 them, the props must be applied at different sides of the beam. 
 The pressures which they sustain may be calculated in the 
 same manner as in the former case. The pressure of the 
 prop B may be considered as a power sustaining the weight 
 W by means of the lever B C. Hence the pressure of B, 
 multiplied by B A, must be equal to the weight W multiplied 
 by A C. Therefore the pressure on B bears the same pro- 
 portion to the weight as A C does to A B. In the same 
 manner, considering B as a fulcrum, and the pressure of the 
 prop A as the power, it may be proved that the pressure of A 
 bears the same proportion to the weight as the line B C does 
 to A B. It therefore appears, that the pressure on the prop 
 A is greater than the weight. 
 
 (246.) When great power is required, and it is incon- 
 venient to construct a long lever, a combination of levers 
 may be used. In Jig. 87. such a system of levers is repre- 
 sented, consisting of three levers of the first kind. The man- 
 ner in which the effect of the power is transmitted to the 
 weight may be investigated by considering the effect of each 
 lever successively. The power at P produces an upward force 
 at P', which bears to P the same proportion as P' F to P F. 
 Therefore the effect at P' is as many times the power as the 
 line P F is of P' F. Thus, if P F be ten times P' F, the 
 upward force at P' is ten times the power. The arm P' F' 
 
148 THE ELEMENTS OF MECHANICS. CHAP. XIII. 
 
 of the second lever is pressed upwards by a force equal to 
 ten times the power at P. In the same manner this may be 
 shown to produce an effect at P" as many times greater 
 than P' as P> F' is greater than P" F'. Thus, if P' F' be 
 twelve times P" F 7 , the effect at P" will be twelve times 
 that of P'. But this last was ten times the power, and there- 
 fore the P" will be one hundred and twenty times the power. 
 In the same manner it may be shown that the weight is as 
 many times greater than the effect at P" r-s P" F" is greater 
 than W F". If P" F" be five times W F", the weight will 
 be five times the effect at P". But this effect is one hundred 
 and twenty times the power, and therefore the weight would 
 be six hundred times the power. 
 
 In the same manner the effect of any compound system 
 of levers may be ascertained by taking the proportion of the 
 weight to the power in each lever separately, and multiplying 
 these numbers together. In the example given, these pro- 
 portions are 10, 12, and 5, which multiplied together give 
 600. In jig. 87. the levers composing the system are of the 
 first kind ; but the principles of the calculation will not be 
 altered if they be of the second or third kind, or some of 
 one kind and some of another. 
 
 (247.) That number which expresses the proportion of the 
 weight to the equilibrating power in any machine, we shall 
 call the power of the machine. Thus, if, in a lever, a power 
 of one pound support a weight of ten pounds, the power of 
 the machine is ten. If a power of 2 Ibs. support a weight of 
 11 Ibs., the power of the machine is 5, 2 being contained in 
 11 5^ times. 
 
 (248.) As the distances of the power and weight from the 
 fulcrum of a lever may be varied at pleasure, and any assign- 
 ed proportion given to them, a lever may always be conceived 
 having a power equal to that of any given machine. Such 
 a lever may be called, in relation to that machine, the equiv- 
 alent lever. 
 
 As every complex machine consists of a number of simple 
 machines acting one upon another, and as each simple ma- 
 chine may be represented by an equivalent lever, the complex 
 machine will be represented by a compound system of equiv- 
 alent levers. From what has been proved in (246.), it there- 
 fore follows that the power of a complex machine may be 
 calculated by multiplying together the powers of the several 
 simple machines of which it is composed. 
 
CHAP. XIV. WHEEL-WORK. 149 
 
 CHAPTER XIV. 
 
 OF WHEEL-WORK. 
 
 (249.) WHEN a lever is applied to raise a weight, or over- 
 come a resistance, the space through which it acts at any one 
 time is small, and the work must be accomplished by a suc- 
 cession of short and intermitting efforts. In Jig. 81., after 
 the weight has been raised from W to W, the lever must 
 again return to its first position, to repeat the action. During 
 this return the motion of the weight is suspended, and it will 
 fall downwards unless some provision be made to sustain it. 
 The common lever is, therefore, only used in cases where 
 weights are required to be raised through small spaces, and 
 under these circumstances its great simplicity strongly rec- 
 ommends it. But where a continuous motion is to be pro- 
 duced, as in raising ore from the mine, or in weighing the 
 anchor of a vessel, some contrivance must be adopted to re- 
 move the intermitting action of the lever, and render it con- 
 tinual. The various forms given to the lever, with a view to 
 accomplish this, are generally denominated the wheel and axle . 
 
 In jig. 88., A B is a horizontal axle, which rests in pivots 
 at its extremities, or is supported in gudgeons, and capable of 
 revolving. Round this axis a rope is coiled, which sustains 
 the weight W. On the same axis a wheel C is fixed, round 
 which a rope is coiled in a contrary direction, to which is 
 appended the power P. The moment of the power is found 
 by multiplying it by the radius of a wheel, and the moment of 
 the weight by multiplying it by the radius of its axle. If these 
 moments be equal (185), the machine will be in equilibrium. 
 Whence it appears that the power of the machine (247.) is 
 expressed by the proportion which the radius of the wheel 
 bears to the radius of the axle : or, what is the same, of the 
 diameter of the wheel to the 1 * diameter of the axle. This 
 principle is applicable to the wheel and axle in every variety 
 of form under which it can be presented. 
 
 (250.) It is evident that as the power descends continually, 
 and the rope is uncoiled from the wheel, the weight will be 
 raised continually, the rope by which it is suspended being at 
 the same time coiled upon the axle. 
 
 When the machine is in equilibrium, the forces of both 
 the weight and power are sustained by the axle, and dis- 
 13 * 
 
150 THE ELEMENTS OP MECHANICS. CHAP. XIV. 
 
 tributed between its props, in the manner explained in 
 
 When the machine is applied to raise a weight, the velocity 
 with which the power moves is as many times greater than 
 that with which the weight rises, as the weight itself is great- 
 er than the power. This is a principle which has already 
 been noticed, and which is common to all machines whatso- 
 ever. It may hence be proved, that in the elevation of the 
 weight a quantity of power is expended equal to that which 
 would be necessary to elevate the weight if the power were 
 immediately applied to it, without the intervention of any 
 machine. This has been explained in the case of the lever 
 in (241.), and may be explained in the present instance in 
 nearly the same words. 
 
 In one revolution of the machine the length of rope un- 
 coiled from the wheel is equal to the circumference of the 
 wheel, and through this space the power must therefore move. 
 At the same time the length of rope coiled upon the axle is 
 equal to the circumference of the axle, and through this space 
 the weight must be raised. The spaces, therefore, through 
 which the power and weight move in the same time, are in 
 the proportion of the circumferences of the wheel and axle ; 
 but these circumferences are in the same proportion as their 
 diameters. Therefore the velocity of the power will bear to 
 the velocity of the weight the same proportion as the diame- 
 ter of the wheel bears to the diameter of the axle, or, what is 
 the same, as the weight bears to the power. (249.) 
 
 (251.) We have here omitted -the consideration of the 
 thickness of the rope. When this is considered, the force 
 must be conceived as acting in the direction of the centre of 
 the rope, and therefore the thickness of the rope which sup- 
 ports the power ought to be added to the diameter of the 
 wheel, and the thickness of the rope which supports the 
 weight to the diameter of the axle. It is the more necessary to 
 attend to this circumstance, as" the strength of the rope neces- 
 sary to support the weight causes its thickness to bear a con- 
 siderable proportion to the diameter of the axle ; while the 
 rope which sustains the power not requiring the same strength, 
 and being applied to a larger circle, bears a very inconsidera- 
 ble proportion to its diameter. 
 
 (252.) In numerous forms of the wheel and axle, the weight 
 or resistance is applied by a rope coiled upon the axle ; but 
 the manner in which the power is applied is very various, and 
 
CHAP. XIV. WINDLASS CAPSTAN TREADMILL. 151 
 
 not often by means of a rope. The circumference of a wheel 
 sometimes carries projecting pins, as represented in Jig. 88., 
 to which the hand is applied to turn the machine. An in- 
 stance of this occurs in the wheel used in the steerage of a 
 vessel. 
 
 In the common windlass, the power is applied by means of 
 a winch, which is a rectangular lever, as represented in Jig. 
 89. The arm B C of the winch represents the radius of the 
 Awheel, and the power is applied to C D at right angles to 
 B C. 
 
 In some cases, no wheel is attached to the axle ; but it is 
 pierced with holes directed towards its centre, in which long 
 levers are incessantly inserted, and a continuous action pro- 
 duced by several men working at the same time ; so that 
 while some are transferring the levers from hole to hole, others 
 are working the windlass. 
 
 The axle is sometimes placed in a vertical position, the 
 wheel or levers being moved horizontally. The capstan is an 
 example of this : a vertical axis is fixed in the deck of the 
 ship ; the circumference is pierced with holes presented to- 
 wards its centre. These holes receive long levers, as rep- 
 resented in jig. 90. The men who work the capstan walk 
 continually round the axle, pressing forward the levers near 
 their extremities. 
 
 In some cases, the wheel is turned by the weight of animals 
 placed at its circumference, who move forward as fast as the 
 wheel descends, so as to maintain their position continually 
 at the extremity of the horizontal diameter. The treadmill 
 fig. 91., and certain cranes, such &sjig. 92., are examples of 
 this. 
 
 In water-wheels, the power is the weight of water contain- 
 ed in buckets at the circumference, as in Jig. 93., which is 
 called an over-shot wheel ; and sometimes the impulse of 
 water against float-boards at the circumference, as in the 
 under-shot wheel, Jig. 94. Both these principles act in the 
 breast-wheel, ^/zg-. 95. 
 
 In the paddle-wheel of a steamboat, the power is the re- 
 sistance which the water offers to the motion of the paddle- 
 boards. 
 
 In windmills, the power is the force of the wind acting on 
 various parts of the arms, and may be considered as different 
 powers simultaneously acting on different wheels having the 
 same axle. 
 
152 THE ELEMENTS OF MECHANICS. CHAP. XIV. 
 
 (253.) In most cases in which the wheel and axle is used, 
 the action of the power is liable to occasional suspension or 
 intermission, in which case some contrivance is necessary to 
 prevent the recoil of the weight. A ratchet wheel H, Jig. 88., 
 is provided for this purpose, which is a contrivance which per- 
 mits the wheel to turn in one direction ; but a catch which 
 falls between the teeth of a fixed wheel, prevents its motion 
 in the other direction. The effect of the power or weight is 
 sometimes transmitted to the wheel or axle by means of a 
 straight bar, on the edge of which teeth are raised, which 
 engage themselves in corresponding teeth on the wheel or axle. 
 Such a bar is called a rack : and an instance of its use may 
 be observed in the manner of working the pistons of an air- 
 pump. 
 
 (254.) The power of the wheel and axle being expressed 
 by the number of times the diameter of the axle is contained 
 in that of the wheel, there are obviously only two ways by 
 which this power may be increased ; viz. either by diminishing 
 the diameter of the axle, or increasing that of the wheel. 
 In cases where great power is required, each of these methods 
 is attended with practical inconvenience and difficulty. If 
 the diameter of the wheel be considerably enlarged, the ma- 
 chine will become unwieldy, and the power will work through 
 an unmanageable space. If, on the other hand, the power of 
 the machine be increased by reducing the thickness of the 
 axle, the strength of the axle will become insufficient for the 
 support of that weight, the magnitude of which had render- 
 ed the increase of the power of the machine necessary. To 
 combine the requisite strength with moderate dimensions and 
 great mechanical power, is, therefore, impracticable in the 
 ordinary form of the wheel and axle. This has, however, 
 been accomplished by giving different thicknesses to different 
 parts of the axle,' and carrying a rope, which is coiled on the 
 thinner part, through a wheel attached to the weight, and coil- 
 ing it in the opposite direction on the thicker part, as \njig. 
 96. To investigate the proportion of the power to the weight 
 in this case, let Jig. 97. represent a section of the apparatus 
 at right angles to the axis. The weight is equally suspended 
 by the two parts of the rope, S and S', and therefore each 
 part is stretched by a force equal to half the weight. The 
 moment of the force, which stretches the rope S, is half the 
 weight multiplied by the radius of the thinner part of the axle. 
 This force, being at the same side of the centre with the pow- 
 
CHAP. XIV. COMPOUND AXLE. 153 
 
 er, co-operates with it in supporting the force which stretches 
 S', and which acts at the other side of the centre. By the 
 principle established in (185.), the moments of P and S must 
 be equal to that of S' : and therefore if P be multiplied by 
 the radius of the wheel, and added to half the weight multi- 
 plied by the radius of the thinner part of the axle, we must 
 obtain a sum equal to half the weight multiplied by the radius 
 of the thicker part of the axle. Hence it is easy to perceive, 
 that the power multiplied by the radius of the wheel is equal 
 to half the weight multiplied by the difference of the radii 
 of the thicker and thinner parts of the axle ; or, what is the 
 same, the power multiplied by the diameter of the wheel 
 is equal to the weight multiplied by half the difference of the 
 diameters of the thinner and thicker parts of the axle. 
 
 A wheel and axle constructed in this manner is equivalent 
 to an ordinary one, in which the wheel has the same diameter, 
 and whose axle has a diameter equal to half the difference of 
 the diameters of the thicker and thinner parts. The power 
 of the machine is expressed by the proportion which the diam- 
 eter of the wheel bears to half the difference of these diam- 
 eters ; and therefore this power, when the diameter of the 
 wheel is given, does not, as in the ordinary wheel and axle, 
 depend on the smallness of the axle, but on the smallness of 
 the difference of the thinner and thicker parts of it. The 
 axle may, therefore, be constructed of such a thickness as to 
 give it all the requisite strength, and yet the difference of the 
 diameters of its different parts may be so small as to give it 
 all the requisite power. 
 
 (255.) It often happens that a varying weight is to be rais- 
 ed, or resistance overcome, by a uniform power. If, in such 
 a case, the weight be raised by a rope coiled upon a uniform 
 axle, the action of the power would not be uniform, but would 
 vary with the weight. It is, however, in most cases desirable 
 or necessary that the weight or resistance, even though it vary, 
 shall be moved uniformly. This will be accomplished if by 
 any means the leverage of the weight is made to increase in 
 the same proportion as the weight diminishes, and to dimin- 
 ish in the same proportion as the weight increases ; for in that 
 case the moment of the weight will never vary, whatever it 
 gains by the increase of weight being lost by the diminished 
 leverage, and whatever it loses by the diminished weight be- 
 ing gained by the increased leverage. An axle, the surface 
 of which is curved in such a manner, that the thickness on 
 
154 THE ELEMENTS OP MECHANICS. CHAP. XIV. 
 
 which the rope is coiled continually increases or diminishes 
 in the same proportion as the weight or resistance diminishes 
 or increases, will produce this effect. 
 
 It is obvious that all that has been said respecting a variable 
 weight or resistance, is also applicable to a variable power, 
 which, therefore, may, by the same means, be made to pro- 
 duce a uniform effect. An instance of this occurs in a watch, 
 which is moved by a spiral spring. When the watch has 
 been wound up, this spring acts with its greatest intensity, 
 and, as the watch goes down, the elastic force of the spring 
 gradually loses its energy. This spring is connected by a 
 chain with an axle of varying thickness, called a fusee. When 
 the spring is at its" greatest intensity, the chain acts upon the 
 thinnest part of the fusee, and as it is uncoiled, it acts upon 
 a part of the fusee which is continually increasing in thick- 
 ness, the spring at the same time losing its elastic power in 
 exactly the same proportion. A representation of the fusee, 
 and the cylindrical box which contains the spring, is given in 
 fig. 98., and of the spring itself in Jig. 99. 
 
 (256.) When great power is required, wheels and axles 
 may be combined in a manner analogous to a compound sys- 
 tem of levers, explained in (246.) In this case the power 
 acts on the circumference of the first wheel, and its effect is 
 transmitted to the circumference of the first axle. That cir- 
 cumference is placed in connection with the circumference of 
 the second wheel, and the effect is thereby transmitted to the 
 circumference of the second axle, and so on. It is obvious 
 from what was proved in (248.), that the power of such a 
 combination of wheels and axles will be found by multiplying 
 together the powers of the several wheels of which it is com- 
 posed. It is sometimes convenient to compute this power by 
 numbers, expressing the proportions of the circumferences or 
 diameters of the several wheels, to the circumferences or di- 
 ameters of the several axles respectively. This computation 
 is made by first multiplying the numbers together which ex- 
 press the circumferences or diameters of the wheels, and then 
 multiplying together the numbers which express the circum- 
 ferences or diameters of the several axles. The proportion 
 of the two products will express the power of the machine. 
 Thus, if the circumferences or diameters be as the numbers 
 10, 14, and 15, their product will be 2100 ; and if the cir- 
 cumferences or diameters of the axles be expressed by the 
 numbers 3, 4, and 5, their product will be 60, and the power 
 
CHAP. XIV. COMPOUND WHEEL-WORK. 155 
 
 of the machine will be expressed by the proportion of 2100 
 and 60, or 35 to 1. 
 
 (257.) The manner in which the circumferences of the 
 axles act upon the circumferences of the wheels in com- 
 pound wheel-work is various. Sometimes a strap or cord is 
 applied to a groove in the circumference of the axle, and 
 carried round a similar groove in the circumference of the 
 succeeding wheel. The friction of this cord or strap with 
 the groove is sufficient to prevent its sliding, and to commu- 
 nicate the force from the axle to the wheel, or vice versd. 
 This method of connecting wheel-work is represented in 
 
 fig- 100. 
 
 Numerous examples of wheels and axles driven by straps 
 or cords occur in machinery, applied to almost every depart- 
 ment of the arts and manufactures. In the turning lathe, 
 the wheel worked by the trcddle is connected with the man- 
 drel by a catgut cord passing through grooves in the wheel 
 and axle. In all great factories, revolving shafts are carried 
 along the apartments, on which, at certain intervals, straps 
 are attached, passing round their circumferences, and carried 
 round the wheels which give motion to the several machines. 
 If the wheels, connected by straps or cords, are required to 
 revolve in the same direction, these cords are arranged as in 
 Jig. 100. ; but if they are required to revolve in contrary 
 directions, they are applied as in Jig. 101. 
 
 One of the chief advantages of the method of transmitting 
 motion between wheels and axles by straps or cords, is, that 
 the wheel and axle may be placed at any distance from each 
 other which may be found convenient, and may be made to 
 turn either in the same or contrary directions. 
 
 (258.) When the circumference of the wheel acts imme- 
 diately on the circumference of the succeeding axle, some 
 means must necessarily be adopted to prevent the wheel from 
 moving in contact with the axle without compelling the latter 
 to turn. If the surfaces of both were perfectly smooth, so 
 that all friction were removed, it is obvious that either would 
 slide over the surface of the other, without communicating 
 motion to it. But, on the other hand, if there were any as- 
 perities, however small, upon these surfaces, they would 
 become mutually inserted among each other, and neither the 
 wheel nor axle could move without causing the asperities 
 with which its edge is studded to encounter those asperities 
 which project from the surface of the other : and thus until 
 
156 THE ELEMENTS OF MECHANICS. CHAP. XIV 
 
 these projections should be broken off, both wheel and axle 
 must be moved at the same time. It is on this account that, 
 if the surfaces of the wheels and axles are by any means 
 rendered rough, and pressed together with sufficient force, the 
 motion of either will turn the other, provided the load or 
 resistance be not greater than the force necesssary to break 
 off these small projections which produce the friction. 
 
 In cases where great power is not required, motion is com- 
 municated in this way through a train of wheel-work, by 
 rendering the surface of the wheel and axle rough, either by 
 facing them with buff leather, or with wood cut across the 
 grain. This method is sometimes used in spinning ma- 
 chinery, where one large buffed wheel, placed in a horizontal 
 position, revolves in contact with several small buffed rollers, 
 each roller communicating motion to a spindle. The position 
 of the wheel W, and the rollers 11 R, &c., are represented 
 in Jig. 102. Each roller can be thrown out of contact with 
 the wheel, and restored to it at pleasure. 
 
 The communication of motion between wheels and axles 
 by friction has the advantage of great smoothness and even- 
 ness, and of proceeding with little noise ; but this method 
 can only be used in cases where the resistance is not very 
 considerable, and, therefore, is seldom adopted in works on a 
 large scale. Dr. Gregory mentions an instance of a saw-mill 
 at Southampton, where the wheels act upon each other by 
 the contact of the end grain of wood. The machinery 
 makes very little noise, and wears very well, having been 
 used not less than 20 years. 
 
 (259.) The most nisual method of transmitting motion 
 through a train of wheel-work is by the formation of teeth 
 upon their circumferences, so that these indentures of each 
 wheel fall between the corresponding ones of that in which 
 it works, and ensure the action so long as the strain is not 
 so great as to fracture the tooth. 
 
 In the formation of teeth, very minute attention must be 
 given to their figure, in order that the motion may be com- 
 municated from wheel to wheel with smoothness and uni- 
 formity. This can only be accomplished by shaping the 
 teeth according to curves of a peculiar kind, which mathe- 
 maticians have invented, and assigned rules for drawing. 
 The ill consequences of neglecting this will be very apparent, 
 by considering the nature of the action which would be pro- 
 duced if the teeth were formed of square projecting pins, as 
 
C1IAI*. XIV. TOOTHED WHEELS. 157 
 
 m fig> 103. When the tooth A comes into contact with B, 
 it acts obliquely upon it, and, as it moves, the corner of B 
 slides upon the plane surface of A in such a manner as to 
 produce much friction, and to grind away the side of A and 
 the end of B. As they approach the position CD, they sus- 
 tain a jolt the moment their surfaces come into full contact ; 
 and after passing the position of C D, the same scraping and 
 grinding effect is produced in the opposite direction, until, 
 by the revolution of the wheels, the teeth become disengaged. 
 These effects are avoided by giving to the teeth the curved 
 forms represented in, fig- 104. By such means the surfaces 
 of the teeth roll upon each other with very inconsiderable 
 friction, and the direction in which the pressure is excited is 
 always that of a line M N, touching the two wheels, and at 
 right angles to the radii. Thus the pressure, being always 
 the same, and acting with the same leverage, produces a 
 uniform effect. 
 
 (260.) When wheels work together, their teeth must 
 necessarily be the same size, and therefore the proportion of 
 their circumferences may always be estimated by the number 
 of teeth which they carry. Hence it follows, that in com- 
 puting the power of compound wheel-work, the number of 
 teeth may always be used to express the circumferences 
 respectively, or the diameters which are proportional to these 
 circumferences. When teeth are raised upon an axle, it is 
 generally called a pinion, and in that case the teeth are called 
 leaves. The rule for computing the train of wheel-work given 
 in (256.) will be expressed as follows : when the wheel and 
 axle carry teeth, multiply together the number of teeth in 
 each of the wheels, and next the number of leaves in each 
 of the pinions ; the proportion of the two products will ex- 
 press the power of the machine. If some of the wheels and 
 axles carry teeth, and others not, this computation may be 
 made by using for those circumferences which do not bear 
 teeth the number of teeth which would fill them. Fig. 105. 
 represents a train of three wheels and pinions. The wheel 
 F which bears the power, and the axle which bears the 
 weight, have no teeth : but it is easy to find the number of 
 teeth which they would carry. 
 
 (261.) It is evident that each pinion revolves much more 
 
 frequently in a given time than the wheel which it drives. 
 
 Thus, if the pinion C be furnished with ten teeth, and the 
 
 wheel E, which it drives, have sixty teeth, the pinion C must 
 
 14 
 
158 THE ELEMENTS OF MECHANICS. CHAP. XIV 
 
 turn six times, in order to turn the wheel E once round. 
 The velocities of revolution of every wheel and pinion which 
 work in one another, will, therefore, have the same proportion 
 as their number of teeth taken in a reverse order, and by this 
 means the relative velocity of wheels and pinions may be de- 
 termined according to any proposed rate. 
 
 Wheel-work, like all other machinery, is used to transmit 
 and modify force in every department of the arts and manu- 
 factures ; but it is also used in cases where motion alone, and 
 not force, is the object to be attained. The most remarkable 
 example of this occurs in watch and clock-work, where the 
 object is merely to produce uniform motions of rotation, 
 having certain proportions, and without any regard to the 
 elevation of weights, or the overcoming of resistances. 
 
 (262.) A crane is an example of combination of wheel- 
 work used for the purpose of raising or lowering great 
 weights. Fig. 106. represents a machine of this kind. 
 A B is a strong vertical beam, resting on a pivot, and secur- 
 ed in its position by beams in the floor. It is capable, 
 however, of turning on its axis, being confined between 
 rollers attached to the beams and fixed in the floor. C D is 
 a projecting arm called a gib, formed of beams which are 
 mortised into A B. The wheel-work is mounted in two cast- 
 iron crosses, bolted on each side of the beams, one of which 
 appears at E F G H. The winch at which the power is ap- 
 plied is at I. This carries a pinion immediately behind H. 
 This pinion works in a wheel K, which carries another 
 pinion upon its axle. This last pinion works in a larger 
 wheel L, which carries upon its axis a barrel M, on which a 
 chain or rope is coiled. The chain passes over a pulley D 
 at the top of the gib. At the end of the chain a hook 
 O is attached, to support the weight W. During the eleva- 
 tion of the weight, it is convenient that its recoil should be 
 hindered in case of any occasional suspension of the power. 
 This is accomplished by a ratchet wheel attached to the bar- 
 rel M, as explained in (253.) ; but when the weight W is to 
 be lowered, the catch must be removed from this ratchet 
 wheel. In this case, the too rapid descent of the weight is 
 in some cases checked by pressure excited on some part of 
 the wheel-work, so as to produce sufficient friction to retard 
 the descent in any required degree, or even to suspend it, if 
 necessary. The vertical beam at B resting on a pivot, and 
 being fixed between rollers, allows the gib to be turned round 
 
CHAP. XIV. REVELLED GEAR. 159 
 
 in any direction ; so that a weight raised from one side of 
 the crane may be carried round, and deposited on another 
 side, at any distance within the range of the gib. Thus, if 
 a crane be placed upon a wharf near a vessel, weights may 
 be raised, and, when elevated, the gib may be turned round 
 so as to let them descend into the hold. 
 
 The power of this machine may be computed upon the 
 principles already explained. The magnitude of the circle, 
 in which the power at I moves, may be determined by the ra- 
 dius of the winch, and therefore the number of teeth which a 
 wheel of that size would carry may be found. In like man- 
 ner, we may determine the number of leaves in a pinion 
 whose magnitude would be equal to the barrel M. Let the 
 first number be multiplied by the number of teeth in the 
 wheel K, and that product by the number of teeth in the 
 wheel L. Next, let the number of leaves in the pinion H be 
 multiplied by the number of leaves in the pinion attached to 
 the axle of the wheel K, and let that product be multiplied 
 by the number of leaves in a pinion whose diameter is equal 
 to that of the barrel M. These two products will express the 
 power of the machine. 
 
 (263.) Toothed wheels are of three kinds, distinguished 
 by the position which the teeth bear with respect to the axis 
 of the wheel. When they are raised upon the edge of the 
 wheel as in Jig. 105., they are called spur wheels or spur gear. 
 When they are raised parallel to the axis, as in Jig. 107., it 
 is called a crown wheel. When the teeth are raised on a sur- 
 face inclined to the plane of the wheel, as \njig. 108., they 
 are called bevelled wheels. 
 
 If a motion round one axis is to be communicated to 
 another axis parallel to it, spur gear is generally used. 
 Thus in Jig. 105., the three axes are parallel to each other. 
 If a- motion round one axis is to be communicated to another 
 at right angles to it, a crown wheel, working in a spur pinion, 
 as in Jig. 107., will serve. Or the same object may be ob- 
 tained by two bevelled wheels, as in Jig. 108. 
 
 If a motion round one axis is required to be communicated 
 to another inclined to it at any proposed angle, two bevelled 
 wheels can always be used. \\\.jig. 109., let A B and A C 
 be the two axles ; two bevelled wheels, such as D E and E F, 
 on these axles will transmit the motion or rotation from one 
 to the other, and the relative velocity may, as usual, be regu- 
 lated by the proportional magnitude of the wheels. 
 
160 THE ELEMENTS OF MECHANICS. CHAP. XIV. 
 
 (264.) In order to equalize the wear of the teeth of a 
 wheel and pinion, which work in one another, it is necessary 
 that every leaf of the pinion should work in succession 
 through every tooth of the wheel, and not continually act 
 upon the same set of teeth. If the teeth could be accurately 
 shaped according to mathematical principles, and the mate- 
 rials of which they are formed be perfectly uniform, this 
 precaution would be less necessary ; but as slight inequalities, 
 both of material and form, must necessarily exist, the effects 
 of these should be as far as possible equalized, by distributing 
 them through every part of the wheel. For this purpose, it 
 is usual, especially in mill-work, where considerable force is 
 used, so to regulate the proportion of the number of teeth in 
 the wheel and pinion, that the same leaf of the pinion shall 
 not be engaged twice with any one tooth of the wheel, until 
 after the action of a number of teeth, expressed by the prod- 
 uct of the number of teeth in the wheel and pinion. Let 
 us suppose that the pinion contains ten leaves, which we 
 shall denominate by the numbers 1, 2, 3, &,c., and that the 
 wheel contains 60 teeth similarly denominated. At the 
 commencement of the motion, suppose the leaf 1 of the pin- 
 ion engages the tooth 1 of the wheel; then after one. revolu- 
 tion the leaf 1 of the pinion will engage the tooth 11 of the 
 wheel, and after two revolutions the leaf 1 of the pinion will 
 engage the tooth 21 of the wheel, and in like manner, after 
 8, 4, and 5 revolutions of the pinion, the leaf 1 will engage 
 successively the teeth 31, 41, and 51 of the wheel. After the 
 sixth revolution, the leaf 1 of the pinion will engage the 
 tooth 1 of the wheel. Thus it is evident, that, in the case 
 here supposed, the leaf 1 of the pinion will continually be 
 engaged with the teeth 1,11, 21, 31, 41, and 51 of the 
 wheel, and no others. The like may be said of every leaf 
 of the pinion. Thus the leaf 2 of the pinion will bo succes- 
 ively engaged with the teeth 2, 12, 22, 32, 42, and 52 of 
 the wheel, and no others. Any accidental inequalities of 
 these teeth will therefore continually act upon each other, 
 until the circumference of the wheel be divided into parts of 
 ten teeth each, unequally worn. This eifect would be 
 avoided by giving either the wheel or pinion one tooth more 
 or one tooth less. Thus, suppose the wheel, instead of hav- 
 ing sixty teeth, had sixty-one, then after six revolutions of 
 the pinion the leaf 1 of the pinion would be engaged with 
 the tooth 61 of the wheel : and after one revolution of th 
 
CHAP. XIV. WATCH AND CLOCK-WORK. 161 
 
 wheel, the leaf 2 of the pinion would he engaged with the 
 tooth 1 of the wheel. Thus, during the first revolution of 
 the wheel, the leaf 1 of the pinion would he successively en- 
 gaged with the teeth 1, 11, 21, 31, 41, 51, and 61 of the 
 wheel ; at the commencement of the second revolution of 
 the wheel the leaf 2 of the pinion would be engaged with 
 the tooth 1 of the wheel ; and during the second revolution 
 of the wheel the leaf 1 of the pinion would be successively 
 engaged with the teeth 10,20,30,40,50, and 60 of the 
 wheel. In the same manner it may be shown, that in the 
 third revolution of the wheel the leaf 1 of the pinion would 
 be successively engaged with the teeth 9, 19, 29, 39, 49, and 
 59 of the wheel ; during the fourth revolution of the wheel, 
 the leaf 1 of the pinion would be successively engaged with 
 the teeth, 8, 18, 28, 38, 48, and 58 of the wheel. By con- 
 tinuing this reasoning it will appear, that during the tenth 
 revolution of the wheel the leaf 1 of the pinion will be en- 
 gaged successively with the teeth 2, 12, 22, 32, 42, and 52 
 of the wheel. At the commencement of the eleventh revo- 
 lution of the wheel the leaf 1 of the pinion will be engaged 
 with the tooth 1 of the wheel, as at the beginning of the 
 motion. It is evident, therefore, that during the first ten 
 revolutions of the wheel each leaf of the pinion has been 
 successively engaged with every tooth of the wheel, and that 
 during these ten revolutions the pinion has revolved sixty-one 
 times. Thus the leaves of the pinion have acted six hun- 
 dred and ten times upon the teeth of the wheel, before two 
 teeth can have acted twice upon each other. 
 
 The odd tooth which produces this effect is called by mill- 
 wrights the hunting cog. 
 
 (265.) The most familiar case in which wheel-work is 
 used to produce and regulate motion merely, without any 
 reference to weights to be raised or resistances to be over- 
 come, is that of chronometers. In watch and clock-work, 
 the object is to cause a wheel to revolve with a uniform ve- 
 locity, and at a certain rate. The motion of this wheel is 
 indicated by an index or hand placed upon its axis, and 
 carried round with it. In proportion to the length of the 
 hand, the circle over which its extremity plays is enlarged, 
 and its motion becomes more perceptible. This circle 
 is divided, so that very small fractions of a revolution of the 
 hand may be accurately observed. In most chronometers, it 
 is required to give motion to two hands, and sometimes to 
 14 * 
 
THE ELEMENTS OF MECHANICS. CHAP. XIV. 
 
 three. These motions proceed at different rates, according 
 to the subdivisions of time generally adopted. One wheel 
 revolves in a minute, hearing a hand which plays round a 
 circle divided into sixty equal parts; the motion of the hand 
 over each part indicating one second, and a complete revolu- 
 tion of the hand being performed in one minute. Another 
 wheel revolves once, while the former revolves sixty times ; 
 consequently the hand carried by this wheel revolves once in 
 sixty minutes, or one hour. The circle on which it plays is 
 like the former, divided into sixty equal parts, and the motion 
 of the hand over each division is performed in one minute. 
 This is generally called the minute, hand, and the former the 
 second hand. 
 
 A third wheel revolves once, while that which carries the 
 minute hand revolves twelve times; consequently this last 
 wheel, which carries the hour hand, revolves at a rate twelve 
 times less than that of the minute hand, and therefore seven 
 hundred and twenty times less than the second hand. We 
 shall now endeavor to explain the manner in which these 
 motions are produced and regulated. Let A, B, C, D, E, 
 fig. 110., represent a train of wheels, and , b, r, d, repre- 
 sent their pinions, e being a cylinder on the axis of the wheel 
 E, round which a rope is coiled, sustaining a weight W. 
 Let the effect of this weight, transmitted through the train 
 of wheels, be opposed by a power P acting upon the wheel A, 
 and let this power be supposed to be of such a nature as to 
 cause the weight W to descend with a uniform velocity, and 
 at any proposed rate. The wheel E carries on its circumfer- 
 ence eighty-four teeth. The wheel D carries eighty teeth ; 
 the wheel C is also furnished with eighty teeth, and the 
 wheel B with seventy-five. The pinions d and c are each fur- 
 nished with twelve leaves, and the pinions b and a with ten. 
 
 If the power at P be so regulated as to allow the wheel A 
 to revolve once in a minute, with a uniform velocity, a hami 
 attached to the axis of this wheel will serve as the second 
 hand. The pinion a carrying ten teeth must revolve seven 
 times and a half to produce one revolution of B, consequent- 
 ly fifteen revolutions of the wheel A will produce two revolu- 
 tions of the wheel B ; the wheel B, therefore, revolves twice 
 in fifteen minutes. The pinion b must revolve eight times 
 to produce one revolution of the wheel C> and therefore the 
 wheel C must revolve once in four quarters of an hour, or 
 in one hour. If a hand be attached to the axis of this 
 
CHAP. XIV. CLOCK-WORK PENDULUM. 163 
 
 wheel, it will have the motion necessary for the minute hand. 
 The pinion c must revolve six times and two thirds to produce 
 one revolution of the wheel D, and therefore this wheel must 
 revolve once in six hours and two thirds. The pinion d 
 revolves seven times for one revolution of the wheel E, and 
 therefore the wheel E will revolve once in forty-six hours and 
 two thirds. 
 
 On the axis of the wheel C a second pinion may be placed, 
 furnished with seven leaves, which may lead a wheel of eighty- 
 four teeth, so that this wheel shall turn once during twelve 
 turns of the wheel C. If a hand be fixed upon the axis, 
 this hand will revolve once for twelve revolutions of the min- 
 ute hand fixed upon the axis of the wheel- C ; that is, it will 
 revolve once in twelve hours. If it play upon a dial divi- 
 ded into twelve equal parts, it will move over each part in an 
 lur.ir, ;i:i<l will serve the purpose of the hour hand of the 
 chronometer. 
 
 We have here supposed that the second hand, the minute 
 hand and the hour hand move on separate dials. This, how- 
 ever, is not necessary. The axis of the hour hand is com- 
 monly a tube, enclosing within it that of the minute hand, so 
 that the same dial serves for both. The second hand, how- 
 ever, is generally furnished with a separate dial. 
 
 (266.) We shall now explain the manner in which a power 
 is applied to the wheel A, so as to regulate and equalize the 
 effect of the weight W. Suppose the wheel A furnished 
 with thirty teeth, as in Jig. 111.; if nothing check the mo- 
 tion, the weight W would descend with an accelerated velocity, 
 and would communicate an accelerated motion to the wheel 
 A. This effect, however, is interrupted by the following 
 contrivance : L M is a pendulum vibrating on the centre L, 
 and so regulated that the time of its oscillation is one second. 
 The pallets 1 and K are connected with the pendulum, so as 
 to oscillate with it. In the position of the pendulum repre- 
 sented in the figure, the pallet I stops the motion of the wheel 
 A, and entirely suspends the action of the weight W ,Jig. 110., 
 KO that for a moment the entire machine is motionless. The 
 weight M, however, falls by its gravity towards tiie lowest 
 position, and disengages the pallet I from the tooth of the 
 wheel. The weight W begins then to take effect, and the 
 wheel A turns from A towards B. Meanwhile the pendulum 
 M oscillates to the other side, and the pallet K falls under 
 a tooth of the wheel A, and checks for a moment its further 
 
164 THE ELEMENTS OF MECHANICS. CHAP. XIV. 
 
 motion. On the returning vibration, the pallet K becomes 
 again disengaged, and allows the tooth of the wheel to escape, 
 and by the influence of the weight W another tooth passes 
 before the motion of the wheel A is again checked by the 
 interposition of the pallet I. 
 
 From this explanation it will appear that, in two vibrations 
 of the pendulum, one tooth of the wheel A passes the pallet 
 I, and, therefore, if the wheel A be furnished with 30 teeth, 
 it will be allowed to make one revolution during 60 vibrations 
 of the pendulum. If, therefore, the pendulum be regulated 
 so as to vibrate seconds, this wheel will revolve once in a 
 minute. From the action of the pallets in checking the mo- 
 tion of the wheel A, and allowing its leeth alternately to 
 escape, -this has been called the cur ape went wheel ; and the 
 wheel and pallets together are generally called the csccipcment 
 or 'scapement. 
 
 We have already explained, that by reason of the frictioa 
 on the points of support, and other causes, the swing of the 
 pendulum would gradually diminish, and its vibration at length 
 cease. This, however, is prevented by the action of the 
 teeth of the scapement wheel upon the pallets, which is just 
 sufficient to communicate that quantity of force to the pen- 
 dulum which is necessary to counteract the retarding effects, 
 and to maintain its motion. It thus appears, that although 
 the effect of the gravity of the weight W in giving motion to 
 the machine is at intervals suspended, yet this part of the 
 force is not lost, being, during these intervals, employed in 
 giving to the pendulum all that motion which it would lose 
 by the resistances to which it is inevitably exposed. 
 
 In stationary clocks, and in other cases in which the bulk 
 of the machine is not au objection, a descending weight is 
 used as the moving power. But in watches and portable 
 chronometers, this would be attended with evident inconve- 
 nience. In such cases, a spiral spring, called the main spring, 
 is the moving power. The manner in which this spring 
 communicates rotation to an axis, and the ingenious method 
 of equalizing the effect of its variable elasticity by giving 
 to it a leverage, which increases as the elastic force dimin- 
 ishes, has been already explained. (255.) 
 
 A similar objection lies against the use of a pendulum in 
 portable chronometers. A spiral spring of a similar kind, 
 but infinitely more delicate, called a hair S2)ring, is substi- 
 tuted in its place. This spring is connected with a nicely 
 
CHAP. XIV. WATCH AND CLOCK-WORK. 165 
 
 balanced wheel, called the balance wheel) which plays in piv- 
 ots. When this wheel is turned to a certain extent in one di- 
 rection, the hair spring is coiled up, and its elasticity causes the 
 wheel to recoil, and return to a position in which the energy 
 of the spring acts in the opposite direction. The balance 
 wheel then returns, and continually vibrates in the same man- 
 ner. The axis of this wheel is furnished with pallets similar 
 to those of the pendulum, which are alternately engaged 
 with the teeth of a crown wheel, which takes the place of the 
 scapement wheel already described. 
 
 A general view of the work of a common watch is repre- 
 sented in jig. 111. bis. A is the balance wheel bearing 
 pallets p p upon its axis ; C is the crown wheel, whose teeth 
 are suffered to escape alternately by those pallets in the man- 
 ner already described in the scapement of a clock. On the 
 axis of the crown wheel is placed a pinion d, which drives 
 another crown wheel K. On the axis of this is placed the 
 pinion , which plays in the teeth of the third wheel L. The 
 pinion b on the axis of L is engaged with the wheel M, called 
 the centre wheel. The axle of this wheel is carried up 
 through the centre of the dial. A pinion a is placed upon it, 
 which works in the great wheel N. On this wheel the main 
 spring immediately acts. O P is the main spring stripped 
 of its barrel. The axis of the wheel M passing through the 
 centre of the dial is squared at the end to receive the minute 
 hand. A second pinion Q, is placed upon this axle, which 
 drives a wheel T. On the axle of this wheel a pinion g 
 is placed, which drives the hour wheel V. This wheel is 
 placed upon a tubular axis, which encloses within it the axis 
 of the wheel M. This tubular axis, passing through the 
 centre of the dial, carries the hour hand. The wheels A, B, 
 C, D, E, Jig. 110., correspond to the wheels C, K, L, M, N, 
 Jig. 112. ; and the pinions , b, r, e?, p, Jig. 109., correspond 
 to the pinions d y r, b, a, Jig. 111. From what has already 
 been explained of these wheels, it will be obvious that the 
 wheel M, jfc, 111., revolves once in an hour, causing the 
 minute hand to move round the dial once in that time. This 
 wheel at the same time turns the pinion Q, which leads the 
 wheel T. This wheel again turns the pinion g, which leads 
 the hour wheel V. The leaves and teeth of these pinions and 
 wheels are proportioned, as already explained, so that the 
 wheel V revolves once during twelve revolutions of the wheel 
 M. The hour hand, therefore, which is carried by the tubu- 
 
166 THE ELEMENTS OF MECHANICS. CHAP. XV. 
 
 lar axle of the wheel V, moves once round the dial in twelve 
 hours. 
 
 Our object here has not been to give a detailed account 
 of watch and clock-work, a subject for which we must refer 
 the reader to the proper department of this work. Such a 
 general account has only been attempted as may explain how 
 tooth and pinion work may be applied to regulate motion. 
 
 CHAPTER XV. 
 
 OP THE PULLEY. 
 
 (267.) THE next class of simple machines, which present 
 themselves to our attention, is that which we have called the 
 cord. If a rope were perfectly flexible, and were capable 
 of being bent over a sharp edge, and of moving upon it with- 
 out friction, we should be enabled by its means to make a 
 force in any one direction overcome resistance, or communi- 
 cate motion in any other direction. Thus if P, Jig. 112., be 
 such an edge, a perfectly flexible rope passing over it would 
 be capable of transmitting a force S F to a resistance Q, R, 
 so as to support or overcome R, or by a motion in the direc- 
 tion of S F to produce another motion in the direction R Q. 
 But as no materials of which ropes can be constructed can 
 give them perfect flexibility, and as, in proportion to the 
 strength by which they are enabled to transmit force, their 
 rigidity increases, it is necessary, in practice, to adopt means 
 to remove or mitigate those effects which attend imperfect 
 flexibility, and which would otherwise render cords practically 
 inapplicable as machines. 
 
 When a cord is used to transmit a force from one direction 
 to another, its stiffness renders some force necessary in bend- 
 ing it over the angle P, which the two directions form ; and 
 if the angle be sharp, the exertion of such a force may be 
 attended with the rupture of the cord. If, instead of bending 
 the rope at one point over a single angle, the change of direc- 
 tion were produced by successively deflecting it over several 
 angles, each of which would be less sharp than a single one 
 could be, the force requisite for the deflection, as well as 
 the liability of rupturing the cord, would be considerably 
 
CHAP. XV. FIXED FULI.EIT. 167 
 
 diminished. But this end will be still more perfectly attained 
 if the deflection of the cord be produced by bending it over 
 the surface of a curve. 
 
 If a rope were applied only to sustain, and not to move a 
 weight, this would be sufficient to remove the inconveniences 
 arising from its rigidity. But when motion is to be produced, 
 the rope, in passing over the curved surface, would be subject 
 to excessive friction, and consequently to rapid wear. This 
 inconvenience is removed by causing the surface on which 
 the rope runs to move with it, so that no more friction is pro- 
 duced than would arise from the curved surface rolling upon 
 the rope. 
 
 (268.) All these ends are attained by the common pulley, 
 which consists of a wheel called a sheave, fixed in a block 
 and turning on pivots. A groove is formed in the edge of the 
 wheel, in which the rope runs, the wheel revolving with it 
 Such an apparatus is represented in jig. 113, 
 
 We shall, for the present, omit the consideration of that 
 part of the effects of the stiffness and friction of the machine, 
 which is not removed by the contrivance just explained, and 
 shall consider the rope as perfectly flexible, and moving with- 
 out friction. 
 
 From the definition of a flexible cord, it follows, that its 
 tension, or the force by which it is stretched throughout its 
 entire length, must be uniform. From this principle, and 
 this alone, all the mechanical properties of pulleys may be de- 
 rived. 
 
 Although, as already explained, the whole mechanical effi- 
 cacy of this machine depends on the qualities of the cord, 
 and not on those of the block and sheave, which are only 
 introduced to remove the accidental effects of stiffness and 
 friction, yet it has been usual to give the name pulley to 
 the block and sheave, and a combination of blocks, sheaves 
 and ropes is called a tackle. 
 
 (269.) When the rope passes over a single wheel, which 
 is fixed in its position, as in Jig. 113., the machine is called 
 a fixed pulley. Since the tension of the cord is uniform 
 throughout its length, it follows, that *in this machine the 
 power and weight are equal. For the weight stretches that 
 part of the cord which is between the weight and pulley, 
 and the power stretches that part between the power and the 
 pulley. And since the tension throughout the whole length 
 is the same, the weight must be equal to the power. 
 
168 THE ELEMENTS OF MECHANICS. CHAP. XV. 
 
 Hence it appears, that no mechanical advantage is gained 
 by this machine. Nevertheless, there is scarcely any engine, 
 simple or complex, attended with more convenience. In the 
 application of power, whether of men or animals, or arising 
 from natural forces, there are always some directions in which 
 it may be exerted to much greater convenience and advantage 
 than others, and in many cases the exertion of these powers 
 is limited to a single direction. A machine, therefore, which 
 enables us to give the most advantageous direction to the 
 moving power, whatever be the direction of the resistance 
 opposed to it, contributes as much practical convenience, as 
 one which enables a small power to balance or overcome a 
 great weight. In directing the power against the resistance, 
 it is often necessary to use two fixed pulleys. Thus, in ele- 
 vating a weight A, Jig. 114., to the summit of a building, by 
 the strength of a horse moving below, two fixed pulleys, B 
 and C, may be used. The rope is carried from A over the 
 pulley B ; the rope passes, and, returning downwards, is 
 brought under C, and finally drawn by the animal on the 
 horizontal plane. In the same manner sails are spread, and 
 flags hoisted on the yards and masts of a ship, by sailors pull- 
 ing a rope on the deck. 
 
 By means of the fixed pulley a man may raise himself to a 
 considerable height, or descend to any proposed depth. If 
 he be placed in a chair or bucket attached to one end of a 
 rope, which is carried over a fixed pulley, by laying hold of 
 this rope on the other side, as represented in Jig- 115,, he 
 may, at will, descend to a depth equal to half of the entire 
 length of the rope, by continually yielding rope on the one 
 side, and depressing the bucket or chair by his weight on 
 the other. Fire-escapes have been constructed on this prin- 
 ciple, the fixed pulley being attached to some part of the 
 building. 
 
 (270.) A single movable pulley is represented in Jig. 116. 
 A cord is carried from a fixed point F, and, passing through 
 a block B, attached to a weight W, passes over a fixed pulley 
 C, the power being applied at P. We shall first suppose the 
 parts of the cord on 'each side the wheel B to be parallel ; 
 in this case, the whole weight W being sustained by the 
 parts of the cords B C and B F, and these parts being equal- 
 ly stretched (268.), each must sustain half the weight, which 
 is therefore the tension of the cord. This tension is resisted 
 by the power at P, which must, therefore, be equal to hajf 
 
CHAP. XV. COMPOUND PULLEYS. 169 
 
 the weight. In this machine, therefore, the weight is twice 
 the power. 
 
 (271.) If the parts of the cord B C and B F be not paral- 
 lel, as in Jig. 117., a greater power than half the weight 
 is therefore necessary to sustain it. To determine the power 
 necessary to support a given weight, in this case take the line 
 B A in the vertical direction, consisting of as many inches 
 as the weight consists of ounces ; from A draw A D parallel 
 to B C, and A E parallel to B F ; the force of the weight 
 represented by A B will be equivalent to two forces repre- 
 sented by B D and B E. (74.) The number of inches in 
 these lines respectively will represent the number of ounces 
 which are equivalent to the tensions of the parts B F and B C 
 of the cord. But as these tensions are equal, B D and B E 
 must be equal, and each will express the amount of the power 
 P, which stretches the cord at P C. 
 
 It is evident that the four lines, A E, E B, B D, and D A, 
 are equal. And as each of them represents the power, the 
 weight which is represented by A B must be less than twice 
 the power which is represented by A E and E B taken 
 together. It follows, therefore, that as parts of the rope? 
 which support the weight depart from parallelism, the machine 
 becomes less. and less efficacious; and there are certain ob- 
 liquities at which the equilibrating power would be much 
 greater than the weight. 
 
 (272.) The mechanical power of pulleys admits of being 
 almost indefinitely increased by combination. Systems of 
 pulleys may be divided into two classes ; those in which a 
 single rope is used, and those which consist of several .dis- 
 tinct ropes. Figs. 118. and 119. represent two systems of 
 pulleys, each having a single rope. The weight is in each 
 case attached to a movable block B, in which are fixed two 
 or more wheels ; A is a fixed block, and the rope is succes- 
 sively passed over the wheels above and below, and, after 
 passing over the last wheel above, is attached to the power. 
 The tension of that part of the cord to which the power is 
 attached is produced by the power, and therefore equivalent 
 to it, and the same tension must extend throughout its whole 
 length. The weight is sustained by all those parts of the cord* 
 which pass from the lower block, and, as the force which 
 stretches them all is the same, viz. that of the power, the ef- 
 fect of the weight must be equally distributed among them, 
 their directions being supposed to be parallel. It will be 
 15 
 
170 THE ELEMENTS OF MECHANICS. CHAP. XV. 
 
 evident, from this reasoning, that the weight will be as many 
 times greater than the power, as the number of cords which 
 support the lower block. Thus, if there be six cords, each 
 cord will support a sixth part of the weight, that is, the weight 
 will be six times the tension of the cord, or six times the pow- 
 er. In Jig. 118. the cord is represented as being finally at- 
 tached to a hook on the upper block. But it may be carried 
 over an additional wheel fixed in that block, and finally at- 
 tached to a hook in the lower block, as \njig. 119., by which 
 one will be added to the power of the machine, the number 
 of cords at the lower block being increased by one. In the 
 system represented in Jig. 118. the wheels are placed in the 
 blocks one above the other; in Jig. 119. they are placed side 
 by side. In all systems of pulleys of this class, the weight of 
 the lower block is to be considered as a part of the weight to 
 be raised, and, in estimating the power of the machine, this 
 should always be attended to. 
 
 (273.) When the power of the machine, and therefore the 
 number of wheels, is considerable, some difficulty arises in 
 the arrangement of the wheels and cords. The celebrated 
 Smeaton contrived a tackle, which takes its name from him, 
 in which there are ten wheels in each block ; five large wheels 
 placed side by side, and five smaller ones similarly placed 
 above them in" the lower block, and below them in the upper. 
 Fig. 120. represents Smeaton's blocks without the rope. The 
 wheels are marked with the numbers 1, 2, 3, &.C., in the or- 
 der in which the rope is to be passed over them. As in this 
 pulley, 20 distinct parts of the rope support the lower block, 
 the weight, including the lower block, will be 20 times the 
 equilibrating power. 
 
 (274.) In all these systems of pulleys, every wheel has a 
 separate axle, and there is a distinct wheel for every turn of 
 the rope at each block. Each wheel is attended with friction 
 on its axle, and also with friction between the sheave and 
 block. The machine is by this means robbed of a great part 
 of its efficacy, since, to overcome the friction alone, a consid- 
 erable power is in most cases necessary. 
 
 An ingenious contrivance has been suggested, by which all 
 the advantage of a large number of wheels may be obtained 
 without the multiplied friction of distinct sheaves and axles. 
 To comprehend the excellence of this contrivance, it will be 
 necessary to consider the rate at which the rope passes over 
 the several wheels of such a system, &sjig. 118. If one foot 
 
CHAP. xv. WHITE'S PULLEY. 171 
 
 of the rope G F pass over the pulley F, two feet must pass 
 over the pulley E, because the distance between F and E 
 being shortened one foot, the total length of the rope G F E 
 must be shortened two feet. These two feet of rope must 
 pass in the direction E D, and the wheel D, rising one foot, 
 three feet of rope must consequently pass over it. These three 
 feet of rope passing in the direction D C, and the rope D C 
 being also shortened one foot by the ascent of the lower block, 
 four feet of rope must pass over the wheel C. In the same 
 way it may be shown that five feet must pass over B, and six 
 feet over A. Thus, whatever be the number of wheels in 
 the upper and lower blocks, the parts of the rope which pass 
 in the same time over the wheels in the lower block are in 
 the proportion of the odd numbers 1, 3, 5, &c. ; and those 
 which pass over the wheels in the upper block in the same 
 time, are as the even numbers 2, 4, 6, &c. If the wheels 
 were all of equal size, as in jig. 119., they would revolve with 
 velocities proportional to the rate at which the rope passes 
 over them : so that, while the first wheel below revolves once, 
 the first wheel above will revolve twice : the second wheel be- 
 low three times ; the second wheel above four times, and so 
 on. If, however, the wheels differed in size in proportion to 
 the quantity of rope which must pass over them, they would 
 evidently revolve in the same time. Thus, if the first wheel 
 above were twice the size of the first wheel below, one revo- 
 lution would throw off twice the quantity of rope. Again, if 
 the second wheel below were thrice the size of the first wheel 
 below, it would throw off in one revolution thrice the quanti- 
 ty of rope, and so on. Wheels thus proportioned, revolving 
 in exactly the same time, might be all placed on one axle, 
 and would partake of one common motion, or, what is to the 
 same effect, several grooves might be cut upon the face of one 
 solid wheel, with diameters in the proportion of the odd num- 
 bers 1, 3, 5, &/c., for the lower pulley, and corresponding 
 grooves on the face of another solid wheel represented by the 
 even numbers 2, 4, 6, &c., for the upper pulley. The rope, 
 being passed successively over the grooves of such wheels, 
 would be thrown off exactly in the same manner as if every 
 groove were upon a separate wheel, and every wheel revolved 
 independently of the others. Such is White's pulley, repre- 
 sented in Jig. 121. 
 
 The advantage of this machine, when accurately construct- 
 ed, is very considerable. The friction, even when great re- 
 
- THE ELEMENTS OP MECHANICS. CHAP. XV. 
 
 sistances are to be opposed, is very trifling ; but, on the other 
 hand, it, has corresponding disadvantages which greatly cir- 
 cumscribe its practical utility. In the workmanship of the 
 grooves, great difficulty is found in giving them the exact pro- 
 portions ; in doing which, the thickness of the rope must be 
 accurately allowed for ; and consequently it follows, that the 
 same pulley can never act, except with a rope of a particular 
 diameter. A very slight deviation from the true proportion 
 of the grooves will cause the rope to be unequally stretched, 
 and will throw on some parts of it an undue proportion of 
 the weight, while other parts become nearly, and sometimes 
 altogether slack. Besides these defects, the rope is so liable 
 to derangement by being thrown out of the grooves, that the 
 pulley can scarcely be considered portable. 
 
 For these and other reasons, this machine, ingenious as it 
 unquestionably is, has never been extensively used. 
 
 (275.) In the several systems of pulleys just explained, the 
 hook to which the fixed block is attached supports the entire 
 of both the power and weight. When the machine is in 
 equilibrium, the power only supports so much of the weight 
 as is equal to the tension of the cord, all the remainder of the 
 weight being thrown on the fixed point, according to what 
 was observed in (225.) 
 
 If the power be moved so as to raise the weight, it will 
 move with a velocity as many times greater than that of the 
 weight, as the weight itself is greater than the power. Thus 
 in jig. 118., if the weight attached to the lower block ascend 
 one foot, six feet of line will pass over the pulley A, accord- 
 ing to what has been already proved. Thus the power will 
 descend through six feet, while the weight rises one foot. 
 But, in this case, the weight is six times the power. All the 
 observations in (226.) will. therefore be applicable to the cases 
 of great weights raised by small powers by means of the sys 
 tern of pulleys just described. 
 
 (276.) When two or more ropes are used, pulleys may be 
 combined in various ways so as to produce any degree of 
 mechanical effect. If to any of the systems already describ- 
 ed, a single movable pulley be added, the power of the ma- 
 chine would be doubled. In this case, the second rope is at- 
 tached to the hook of the lower block, as in Jig. 122., and, 
 being carried through a movable pulley attached to the 
 weight, it is finally brought up to a fixed point. The tension of 
 the second cord is equal to half the weight (270.) ; and there- 
 

 CHAP. XV. SPANISH BARTONS. 173 
 
 fore the power P, by means of the first cord, will have only 
 half the tension which it would have if the weight were at- 
 tached to the lower block. A movable pulley thus applied 
 is called a runner. 
 
 (277.) Two systems of pulleys, called Spanish bartons, 
 having each two ropes, are represented in Jig. 123. The 
 tension of the rope P A B C in the first system is equal to 
 the power ; and therefore the parts B A and B C support a 
 portion of the weight equal to twice the power. The rope 
 E A supports the tensions of A P and A B ; and therefore 
 the tension of A E D is twice the power. Thus the united 
 tensions of the ropes which support the pulley B is four times 
 the power, which is therefore the amount of the weight. In 
 the second system, the rope P A D is stretched by the power. 
 The rope A E B C acts against the united tensions A P and 
 A D ; and therefore the tension of A E or E B is twice the 
 power. Thus the weight acts against three tensions ; two of 
 which are equal to twice the power, and the remaining one is 
 equal to the power. The weight is therefore equal to five 
 times the power. 
 
 A single rope may be so arranged with one movable pul- 
 ley as to support a weight equal to three times the power. 
 In Jig. 124. this arrangement is represented, where the num- 
 bers sufficiently indicate the tension of the rope, and the 
 proportion of the weight and power. In Jig. 125. another 
 method of producing the same effect with two ropes is repre- 
 sented. 
 
 (278.) If several single movable pulleys be made succes- 
 sively to act upon nach other, the effect is doubled by every 
 additional pulley : such a system as this is represented in Jig. 
 126. The tension of the first rope is equal to the power ; the 
 second rope acts against twice the tension of the first, and 
 therefore it is stretched with a force equal to twice the pow- 
 er : the third rope acts against twice this tension, and there- 
 fore it is stretched with a force equal to four times the pow- 
 er; and so on. In the system represented in Jig. 126., there 
 are three ropes, arid the weight is eight times the power. 
 Another rope would render it sixteen times the power, and 
 so on. 
 
 In this system, it is obvious that the ropes will require to 
 have different degrees of strength, since the tension to which 
 they are subject increases in a double proportion from the 
 power to the weight. 
 15 * 
 
174 THE ELEMENTS op MECHANICS. CHAP. xv. 
 
 (279.) If each of the ropes, instead of being attached to 
 fixed points at the top, are carried over fixed pulleys, arid at- 
 tached to the several movable pulleys respectively, is in Jig. 
 127., the power of the machine will be greatly increased ; for 
 in that case the forces which stretch the successive ropes in- 
 crease in a treble instead of a double proportion, as will be 
 evident by attending to the numbers which express the ten- 
 sions in the figure. One rope would render the weight three 
 times the power ; two ropes nine limes; three ropes twenty- 
 seven times; and so on. An arrangement of pulleys is rep- 
 resented in Jig. 128., by which each rope, instead of being 
 finally attached to a fixed point, as hi fig. 126., is attached to 
 the weight. The weight is in this case supported by three 
 ropes ; one stretched with a force equal to the power ; anoth- 
 er with a force equal to twice the power ; and a third with a 
 force equal to four times the power. The weight is, therefore, 
 in this case, seven times the power. 
 
 (280.) If the ropes, instead of being attached to the weight, 
 pass through wheels, as in Ji,g. 129., and are finally attached 
 to the pulleys above, the power of the machine will be con- 
 siderably increased. In the system here represented, the 
 weight is twenty-six times the power. 
 
 (281.) In considering these several combinations of pulleys, 
 we have ^omitted to estimate the effects produced by the 
 weights of the sheaves and blocks. Without entering into 
 the details of this computation, it may be observed generally, 
 that in the systems represented in fig*. 12(3., 127., the weight 
 of the wheel and blocks acts against the power ; but that 
 in Jigs. 128. and 129. they assist the powers in supporting 
 the weight. In the systems represented in Jig. 123., the 
 weights of the pulleys, to a certain extent, neutralize each 
 other. 
 
 (282.) It will in all cases be found, that that quantity by 
 which the weight exceeds the power is supported by fixed 
 points ; and therefore, although it be commonly stated that a 
 small power supports a great weight, yet in the pulley, as in 
 all other machines, the power supports no more of the weight 
 than is exactly equal to its own amount. It will not be 
 necessary to establish this in each of the examples which 
 have been given ; having explained it in one instance, the 
 student will find no difficulty in applying the same reasoning 
 to others. In Jig. 126., the fixed pulley sustains a force equal 
 to twice the power, and by it the oower giving tension to the 
 
CHAP. XV. PULLEYS. 175 
 
 first rope sustains a part of the weight equal to itself. The 
 first hook sustains a portion of the weight equal to the tension 
 of the first string, or to the power. The second hook sus- 
 tains a force equal to twice the power ; and the third hook 
 sustains a force equal to four times the power. The three 
 hooks therefore sustain a portion of the weight equal to seven 
 times the power ; and the weight itself being eight times the 
 power, it is evident that the part of the weight which re- 
 mains to be supported by the power, is equal to the power 
 itself. 
 
 (283.) When a weight is raised by any of the systems of 
 pulleys which have been last described, the proportion between 
 the velocity of the weight and the velocity of the power, so 
 frequently noticed in other machines, will always be observ- 
 ed. In the system of pulleys represented in jig. 126., the 
 weight being eight times the power, the velocity of the pow- 
 er will be eight times that of the weight. If the power be mov- 
 ed through eight feet, that part of the rop between the fixed 
 pulley and the first movable pulley will be shortened by 
 eight feet. And since the two parts which lie above the first 
 movable pulley must be equally shortened, each will be di- 
 minished by four feet ; therefore the first pulley will rise 
 through four feet, while the power moves through eight feet. 
 In the same way it may be shown, that while the first pulley 
 moves through four feet, the second moves through two ; and 
 while the second moves through two, the third, to which the 
 weight is attached, is raised through one foot. While the 
 power, therefore, is carried through eight feet, the weight is 
 moved through one foot. 
 
 By reasoning similar to this, it may be shown that the space 
 through which the power is moved in every case is as many 
 times greater than the height through which the weight is 
 raised, as the weight is greater than the power. 
 
 (284.) From its portable form, cheapness of construetion, 
 and the facility with which it may be applied in almost every 
 situation, the pulley is one of the most useful of the simple 
 machines. The mechanical advantage, however, which it 
 appears in theory to possess, is considerably diminished in 
 practice, owing to the stiffness of the cordage, and the friction 
 of the wheels and blocks. By this means it is computed that 
 in most cases so great a proportion as two thirds of the power 
 is lost. The pulley is much used in building, where weights 
 
 
176 THE ELEMENTS OF MECHANICS. CHAP. XVI. 
 
 are to be elevated to great heights. But its most extensive 
 application is found in the rigging of ships, where almost eve- 
 ry motion is accomplished by its means. 
 
 (285.) In all the examples of pulleys, we have supposed 
 the parts of the rope sustaining the weight, and each of the 
 movable pulleys, to be parallel to each other. If they be 
 subject to considerable obliquity, the relative tensions of the 
 different ropes must be estimated according to the principle 
 applied in (271.) 
 
 CHAPTER XVI. 
 
 ON THE INCLINED PLANE, WEDGE, AND SCREW. 
 
 (286.) THE inclined plane is the most simple of all ma- 
 chines. It is a hard plane surface forming some angle with 
 a horizontal plane, that angle not being a right angle. When 
 a weight is placed on such a plane, a two-fold effect is pro- 
 duced. A part of the effect of the weight is resisted by the 
 plane, and produces a pressure upon it ; and the remainder 
 urges the weight down the plane, and would produce a pres- 
 sure against any .surface resisting its motion placed in a direc- 
 tion perpendicular to the plane (131.) 
 
 Let A B, .jig. 130., be such a plane, B C its horizontal 
 base, A C its height, and A B C its angle of elevation. Let 
 W be a weight placed upon it. This weight acts in the ver- 
 tical direction W D, and is equivalent to two forces, W F 
 perpendicular to the plane, and W E directed down the plane 
 (74.) If a plane be placed at right angles to the inclined 
 plane below W, it will resist the descent of 'ae weight, and 
 sustain a pressure expressed by W E. Thus the weight W, 
 resting in the corner, instead of producing one pressure in the 
 direction W D, will produce two pressures, one expressed by 
 W F upon the inclined plane, and the other expressed by W 
 E upon the resisting plane. These pressures respectively 
 have the same proportion to the entire weight, as W F and 
 W E have to W D, or as D E and W E have to W D, be- 
 cause D E is equal to W F. Now, the triangle WED is 
 in all respects similar to the triangle ABC, the one differ- 
 ing from the other only in the scale on which it is construct- 
 

 CHAP. XVI. INCLINED ROADS. 177 
 
 ed. Therefore the three lines A C, C B, and B A, are in 
 the same proportion to each other as the lines W E, E D, and 
 W D. Hence A B has to A C the same proportion as the 
 whole weight has to the pressure directed towards B, and 
 A B has to B C the same proportion as the whole weight has 
 to the pressure on the inclined plane. 
 
 We have here supposed the weight to be sustained upon 
 the inclined plane, by a hard plane fixed at right angles to it. 
 But the power necessary to sustain the weight will be the 
 same, in whatever way it is applied, provided it act in the di- 
 rection of the plane. Thus a cord may be attached to the 
 weight, and stretched towards A, or the hands of men may 
 be applied to the weight below it, so as to resist its descent 
 towards B. But in whatever way it be applied, the amount of 
 the power will be determined in the same manner. Suppose 
 the weight to consist of as many pounds as there are inches 
 in A B, then the power requisite to sustain it upon the plane 
 will consist of as many pounds as there are inches in A C, 
 and the pressure on the plane will amount to as many pounds 
 as there are inches in B C. 
 
 From what has been stated, it may easily be inferred that 
 the less the elevation of the plane is, the less will be the pow- 
 er requisite to sustain a given weight upon it, and the greater 
 will be the pressure upon it. Suppose the inclined plane 
 A B to turn upon a hinge at B, and to be depressed so that 
 its angle of elevation shall be diminished, it is evident that as 
 this angle decreases, the height of the plane decreases, and 
 its base increases. Thus, when it takes the position B A', 
 the height A' C' is less than the former height A C, while the 
 base B C' is greater than the former base B C. The power 
 requisite to support the weight upon the plane in the position 
 B A' is represented by A' C', and is as much less than the 
 power requisite to sustain it upon the plane A B, as the height 
 A' C' is less than the height A C. On the other hand, the 
 pressure upon the plane in the position B A 7 is as much great- 
 er than the pressure upon the plane B A, as the base B C' is 
 greater than the base B C. 
 
 (287.) The power of an inclined plane, considered as a 
 machine, is therefore estimated by the proportion which the 
 length bears to the height. This power is always increased 
 by diminishing the elevation of the plane. 
 
 Roads which are not lerel may be regarded as inclined 
 planes, and loads drawn upon them in carriages, considered 
 
178 THE ELEMENTS OF MECHANICS. CHAT. XVI. 
 
 in reference to the powers which impel them, are subject to 
 all the conditions which have been established for inclined 
 planes. The inclination of the road is estimated by the 
 height corresponding to some proposed length. Thus it is 
 said to rise one foot in fifteen, one foot in twenty, &,c., mean- 
 ing that if fifteen or twenty feet of the road be taken as the 
 length of an inclined plane, such as A B, the corresponding 
 height will be one foot. Or the same may be expressed thus : 
 that if fifteen or twenty feet be measured upon the roacj, the 
 difference of the levels of the two extremities of the distance 
 measured is one foot. According to this method of estimat- 
 ing the inclination of roads, the power requisite to sustain a 
 load upon them (setting aside the effect of friction) is always 
 proportional to that elevation. Thus, if a road rise one foot 
 in twenty, a power of one ton will be sufficient to sustain 
 twenty tons, and so on. 
 
 On a horizontal plane, the only resistance which the power 
 has to overcome, is the friction of the load with the plane, and 
 the consideration of this being for the present omitted, a 
 weight once put in motion would continue moving for ever, 
 without any further action of the power. But if the plane be 
 inclined, the power will be expended in raising the weight 
 through the perpendicular height of the plane. Thus, in a 
 road which rises one foot in ten, the power is expended in 
 raising the weight through one perpendicular foot for every 
 ten feet of the road over which it is moved. As the expendi- 
 ture of power depends upon the rate at which the weight is 
 raised perpendicularly, it is evident that the greater the incli- 
 nation of the road is, the slower the motion must be with the 
 same force. If the energy of the power be such as to raise 
 the weight at the rate of one foot per minute, the weight may 
 be moved in each minute through that length of the road 
 which corresponds to a rise of one foot. Thus, if two roads 
 rise, one at the rate of a foot in fifteen feet, and the other at 
 the rate of one foot in twenty feet, the same expenditure of 
 power will move the weight through fifteen feet of the one, 
 and twenty feet of the other at the same rate. 
 
 From such considerations as these, it will readily appear 
 that it may often be more expedient to carry a road through a 
 circuitous route than to continue it in the most direct course ; 
 for, though the measured length of road may be considerably 
 greater in the former case, yet more may be gained in 
 speed with the same expenditure of power, than is lost by the 
 
CKAP. XVI. INCLINED PLANE. 179 
 
 increase of distance. By attending to these circumstances, 
 modern road-makers have greatly facilitated and expedited 
 the intercourse between distant places. 
 
 (288.) If the power act oblique to the plane, it will have a 
 twofold effect ; a part being expended in supporting or draw- 
 ing the weight, and a part in diminishing or increasing the 
 pressure upon the plane. Let W P,Jig. 130., be the power. 
 This will be equivalent to two forces, W F', perpendicular to 
 the plane, and W E' in the direction of the plane. (74.) In 
 order that the power should sustain the weight, it is necessary 
 that that part W E' of the power which acts in the direction 
 of the plane, should be equal to that part W E,fg. 130., of 
 the weight which acts down the plane. The other part W F, 
 of the power acting perpendicular to the plane, is immediately 
 opposed to that part W F of the weight which produces pres- 
 sure. The pressure upon the plane will therefore be dimin- 
 ished by the amount of W F'. The amount of the power, 
 which will equilibrate with the weight, may, in this case, be 
 found as follows. Take W E' equal to W E, and draw E' P 
 perpendicular to the plane, and meeting the direction of the 
 power. The proportion of the power to the weight will be 
 that of W P to W D. And the proportion of the pressure to 
 the weight will be that of the difference between W F and 
 W F 7 to W D. If the amount of the power have a less pro- 
 portion to the weight than W P has to W D, it will not sup- 
 port the body on the plane, but will allow it to descend. And 
 if it had a greater proportion, it will draw the weight up the 
 plane towards A. 
 
 (289.) It somet'.nes happens that a weight upon one in- 
 clined plane is raised or supported by another weight upon 
 another inclined plane. Thus, if A B and A R',jig. 131., be 
 two inclined planes, forming an angle at A, and W W be 
 two weights placed upon these planes, and connected by a 
 cord passing over a pulley at A, the one weight will either 
 sustain the other, or one will descend, drawing the other up. 
 To determine the circumstances under which these effects 
 will ensue, draw the lines W D and W D' in the vertical di- 
 rection, and take upon them as many inches as there are 
 ounces in the weights respectively. W D and W D' being 
 the lengths thus taken, and therefore representing the weights, 
 the lines W E and W E' will represent the effects of these 
 weights respectively down the planes. If WE and W E' be 
 equal, the weights will sustain each other without motion. 
 
180 THE ELEMENTS OF MECHANICS. CHAP. XVI 
 
 But if W E be greater than W E', the weight W will de- 
 scend, drawing the weight W' up. And if W E 7 be greater 
 than W E, the weight W' will descend, drawing the weight 
 W up. In every case, the lines W F and W F' will repre- 
 sent the pressures upon the planes respectively. 
 
 It is not necessary, for the effect just described, that the 
 inclined planes should, as represented in the figure, form an 
 angle with each other. They may be parallel, or in any other 
 position, the rope being carried over a sufficient number of 
 wheels placed so as to give it the necessary deflection. This 
 method of moving loads is frequently applied in great public 
 works where rail-roads are used. Loaded wagons descend 
 one inclined plane, while other wagons, either empty or so 
 loaded as to permit the descent of those with which they are 
 connected, are drawn up the other. 
 
 (290.) In the application of the inclined plane, which we 
 have hitherto noticed, the machine itself is supposed to be 
 fixed in its position, while the weight or load is moved upon 
 it. But it frequently happens that resistances are to be over- 
 come which do not admit to be thus moved. In such cases, 
 instead of moving the load upon the planes, the plane is to be 
 moved under or against the load. Let D E,^g\ 132., be a 
 heavy beam secured in a vertical position between guides, F 
 G and H I, so that it is free to move upwards and downwards, 
 but not laterally. Let A B C be an inclined plane, the ex- 
 tremity of which is placed beneath the end of the beam. A 
 force applied to the back of this plane A C, in the direction 
 C B, will .urge the plane under the beam, so as to raise the 
 beam to the position represented in the^zv 133. Thus, while 
 the inclined plane is moved through the distance C B, the 
 beam is raised through the height C A. 
 
 (291.) When the inclined plane is applied in this manner, 
 it is called a wedge. And if the power applied to the back 
 were a continued pressure, its proportion to the weight would 
 be that of A C to C B. It follows, therefore, that the more 
 acute the angle B is, the more powerful will be the wedge. 
 
 In some cases, the wedge is formed of two inclined planes, 
 placed base to base, as represented in Jig. 134. The theoret- 
 ical estimation of the power of this machine is not applicable 
 in practice with any degree of accuracy. This is in part 
 owing to the enormous proportion which the friction in most 
 cases bears to the theoretical value of the power, but still 
 more to the nature of the power generally used. The force 
 
CHAP; xvi. USES OF THE WEDGE. 181 
 
 of a blow is of a nature so wholly different from continued 
 forces, such as the pressure of weights, or the resistance of- 
 fered by the cohesion of bodies, that they admit of no numer- 
 ical comaprison. Hence we cannot properly state the pro- 
 portion which the force of a blow bears to the amount of a 
 weight or resistance. The wedge is almost invariably urged 
 by percussion ; while the resistances which it has to over- 
 come are as constantly forces of the other kind. Although, 
 however, no exact numerical comparison can be made, yet it 
 may be stated in a general way that the wedge is more and 
 more powerful as its angle is more acute. 
 
 In the arts and manufactures, wedges are used where enor- 
 mous force is to be exerted through a very small space. 
 Thus it is resorted to for splitting masses of timber or stone. 
 Ships are raised in docks by wedges driven under their keels. 
 The wedge is the principal agent in the oil-mill. The seeds 
 from which the oil is to be extracted are introduced into hair 
 bags, and placed between planes of hard wood. Wedges in- 
 serted between the bags are driven by allowing heavy beams 
 to fall on them. The pressure thus excited is so intense, that 
 the seeds in the bags are formed into a mass nearly as solid 
 as wood. 
 
 Instances have occurred in which the wedge has been used 
 to restore a tottering edifice to its perpendicular position. All 
 cutting and piercing instruments, such as knives, razors, scis- 
 sors, chisels, &LC., nails, pins, needles, awls, &,c., are wedges. 
 The angle of the wedge, in these cases, is more or less acute, 
 according to the purpose to which it is to be applied. In de- 
 termining this, two things are to be considered the mechan- 
 ical power, which is increased by diminishing the angle of the 
 wedge, and the strength of the tool, which is always dimin- 
 ished by the same cause. There is, therefore, a practical 
 limit to the increase of the power, and that degree of sharp- 
 ness only is to be given to the tool which is consistent with 
 the strength requisite for the purpose to which it is to be ap- 
 plied. In tools intended for cutting wood, the angle is gen- 
 erally about 30. For iron it is from 50 to 60 ; and for 
 brass, from 80 to 90. Tools which act by pressure may be 
 made more acute than those which are driven by a blow ; 
 and, in general, the softer and more yielding the substance to 
 be divided is, and the less the power required to act upon it, 
 the more acute the wedge may be constructed. 
 
 In many cases, the utility of the wedge depends on that 
 16 
 
18S THE ELEMENTS OP MECHANICS. CHAP. XVI. 
 
 which is entirely omitted in its theory, viz. the friction which 
 arises between its surface and the substance which it divides. 
 This is the case when pins, bolts or nails are used for bind- 
 ing the parts of structures together ; in which case, were it 
 not for the friction, they would recoil from their places, and 
 fail to produce the desired effect. Even when the wedge is 
 used as a mechanical engine, the presence of friction is ab- 
 solutely indispensable to its practical utility. The power, as 
 has already been stated, generally acts by successive blows, 
 and is therefore subject to constant intermission, and, but for 
 the friction, the wedge would recoil between the intervals of 
 the blows with as much force as it had been driven forward. 
 Thus the object of the labor would be continually frustrated. 
 The friction, in this case, is of the same use as a ratchet 
 wheel, but is much more necessary, as the power applied to 
 the wedge is more liable to intermission than in the cases 
 where ratchet wheels are generally used. 
 
 (292.) When a road directly ascends the side of a hill, it 
 is to be considered as an inclined plane ; but it will not lose 
 its mechanical character, if, instead of directly ascending 
 towards the top of the hill, it winds successively round it, and 
 gradually ascends, so as, after several revolutions, to reach the 
 top. In the same manner a path may be conceived to sur- 
 round a pillar by which the ascent may be facilitated upon 
 the principle of the inclined plane. Winding stairs con- 
 structed in the interior of great columns partake of this 
 character ; for although the ascent be produced by successive 
 steps, yet if a floor could be made sufficiently rough to pre- 
 vent the feet from slipping, the ascent would be accomplished 
 with equal facility. In such a case, the winding path would 
 be equivalent to an inclined plane, bent into such a form as 
 to accommodate it to the peculiar circumstances in which it 
 would be required to be used. It will not be difficult to trace 
 the resemblance between such an adaptation of the inclined 
 plans and the appearances presented by the thread of a screw: 
 and it may hence be easily understood that a screw is nothing 
 more than an inclined plane constructed upon the surface of 
 a cylinder. 
 
 This will, perhaps, be more apparent by the following con- 
 trivance : Let A B,/g\ 135., be a common round ruler, and 
 let C D E be a piece of white paper cut in the form of an 
 inclined plane, whose height C D is equal to the length of 
 the ruler A B, and let the edge C E of the paper be marked 
 
CHAP. XVI, THE SCREW, " 183 
 
 with a broad black line : let the edge C D be applied to the 
 ruler A B } and, being attached thereto, let the paper be 
 rolled round the ruler ; the ruler will then present the appear- 
 ance of a screw, ^g 1 . 136,, the thread of the screw being 
 marked by the black line C E, winding continually round 
 the ruler. Let D F, jig* 135., be equal to the circumference 
 of the ruler, and draw F G parallel to D C, and G H parallel 
 to D E, the part C G F D of the paper will exactly surround 
 the ruler once ; the part C G will form one spire of the 
 thread, and may be considered as the length of one inclined 
 plane surrounding the cylinder, C H being the corresponding 
 height, and G H the base. The power of the screw does 
 not, as in the ordinary cases of the inclined plane, act par- 
 allel to the plane or thread, but at right 1 angles to the length 
 of the cylinder A B, or, what is to the same effect, parallel 
 to the base H G ; therefore the proportion of the power to 
 the weight will be, according to principles already explained, 
 the same as that of C H to the space through which the 
 power moves parallel to H G in one revolution of the screw. 
 H C is evidently the distance between the successive positions 
 of the thread as it winds round the cylinder ; and it appears, 
 from what has been just stated, that the less this distance is, 
 or, in other words, the finer the thread is, the more powerful 
 the machine will be. 
 
 (293.) In the application of the screw, the weight or re- 
 sistance is not, as in the inclined plane and wedge, placed 
 upon the surface of the plane or thread. The power is usu- 
 ally transmitted by causing the screw to move in a concave 
 cylinder, on the interior surface of which a spiral cavity is 
 cut, corresponding exactly to the thread of the screw, and 
 in which the thread will move by turning round the screw 
 continually in the same direction. This hollow cylinder is 
 usually called the nut or concave screw. The screw surrounded 
 by its spiral thread is represented iiijig. 137. ; and a section 
 of the same playing in the nut is represented in Jig. 138. 
 
 There are several ways in which the effect of the power 
 may be conveyed to the resistance by this apparatus. 
 
 First, let us suppose that the nut A B is fixed. If the 
 screw be continually turned on its axis, by a lever E F in- 
 serted in one end of it, it will be moved in the direction 
 C D, advancing every revolution through a space equal to the 
 distance between two contiguous threads. By turning the 
 lever in an opposite direction, the screw will be moved in the 
 direction D C. 
 
184 THE ELEMENTS OF MECHANICS. CHAP. XVI 
 
 It the screw be fixed, so as to be incapable either of moving 
 longitudinally or revolving on its axis, the nut A B may be 
 turned upon the screw by a lever, and will move on the 
 screw towards C or towards D, according to the direction in 
 which the lever is turned. 
 
 In the former case, we have supposed the nut to be abso- 
 lutely immovable, and in the latter case, the screw to be 
 absolutely immovable. It may happen, however, that the 
 nut, though capable of revolving, is incapable of moving lon- 
 gitudinally ; and that the screw, though incapable of revolving, 
 is capable of moving longitudinally. In that case, by turn- 
 ing the nut A B upon the screw by the lever, the screw will 
 be urged in the direction C D or DC, according to the way 
 in which the nut is turned. 
 
 The apparatus may, on the contrary, be so arranged, that 
 the nut, though incapable of revolving, is capable of moving 
 longitudinally ; and the screw, though capable of revolving, 
 is incapable of moving longitudinally. In this case, by turn- 
 ing the screw in the one direction or in the other, the nut 
 A B will be urged in the direction C D or D C. 
 
 All these various arrangements may be observed in differ- 
 ent applications to the machine. 
 
 (294.) A screw may be cut upon a cylinder by placing 
 the cylinder in a turning lathe, and giving it a rotatory mo- 
 tion upon its axis. The cutting point is then presented to 
 the cylinder, and moved in the direction of its length, at 
 such a rate as to be carried through the distance between the 
 intended thread, while the cylinder revolves once. The rel- 
 ative motions of the cutting point and the cylinder being 
 preserved with perfect uniformity, the thread will be cut 
 from one end to the other. The shape of the threads may be 
 either square, as in Jig. 137., or triangular, as in Jig. 139. 
 
 (295.) The screw is generally used in cases where severe 
 pressure is to be excited through small spaces ; it is therefore 
 the agent in most presses, in Jig. 140., the nut is fixed, and 
 by turning the lever, which passes through the head of the 
 screw, a pressure is excited upon any substance placed upon 
 the plate immediately under the end of the screw. In 
 jig. 141., the screw is incapable of revolving, but is capable 
 of advancing in the direction of its length. On the other 
 hand, the nut is capable of revolving, but does not advance 
 in the direction of the screw. When the nut is turned by 
 
CHAP. XVI. USES OF THE SCREW. 185 
 
 means of the screw inserted in it, the screw advances in the 
 direction of its length, and urges the board which is attached 
 to it upwards, so as to press any substance placed between 
 it and the fixed board above. 
 
 In cases where liquids or juices are to be expressed from 
 solid bodies, the screw is the agent generally employed. It 
 is also used in coining, where the impression of a dye is to 
 be made upon a piece of metal, and in the same way in pro- 
 ducing the impression of a seal upon wax or other substance 
 adapted to receive it. When soft and light materials, such 
 as cotton, are to be reduced to a convenient bulk for transpor- 
 tation, the screw is used to compress them, and they are thus 
 reduced into hard, dense masses. In printing, the paper is 
 urged by a severe and sudden pressure upon the types, by 
 means of a screw. 
 
 (296.) As the mechanical power of the screw depends 
 upon the relative magnitude of the circumference through 
 which the power revolves, and the distance between the 
 threads, it is evident, that, to increase the efficacy of the 
 machine, we must either increase the length of the lever by 
 which the power acts, or diminish the magnitude of the 
 thread. Although there is no limit in theory to the increase 
 of the mechanical efficacy by these means, yet practical in- 
 convenience arises which effectually prevents that increase 
 being carried beyond a certain extent. If the lever by 
 which the power acts be increased, the same difficulty arises 
 as was already explained in the wheel and axle (254.) ; the 
 space through which the power should act would be so un- 
 wieldy, that its application would become impracticable. If, 
 on the other hand, the power of the machine be increased 
 by diminishing the size of the thread, the strength of the 
 thread will be so diminished, that a slight resistance will 
 tear it from the cylinder. The cases in which it is necessary 
 to increase the power of the machine being those in which 
 the greatest resistances are to be overcome, the object will 
 evidently be defeated, if the means chosen to increase that 
 power deprive the machine of the strength which is necessary 
 to sustain the force to which it is to be submitted. 
 
 (297.) These inconveniences are removed by a contrivance 
 of Mr. Hunter, which, while it gives to the machine all the 
 requisite strength and compactness, allows it to have an 
 almost unlimited degree of mechanical efficacy. 
 
 This contrivance consists in the use of two screws, the 
 16* 
 
186 THE ELEMENTS OP MECHANICS. CHAP. XVI. 
 
 threads of which may have any strength and magnitude, but 
 which have a very small difference of breadth. While the 
 working point is urged forward by that which has the greater 
 thread, it is drawn back by that which has the less ; so that, 
 during each revolution of the screw, instead of being ad- 
 vanced through a space equal to the magnitude of either of 
 the threads, it moves through a space equal to their differ- 
 ence. The mechanical power of such a machine will be the 
 same as that of a single screw having a thread, whose mag- 
 nitude is equal to the difference of the magnitudes of the 
 two threads just mentioned. 
 
 Thus, without inconveniently increasing the sweep of the 
 power, on the one hand, or, on the other, diminishing the 
 thread until the necessary strength is losj;, the machine will 
 acquire an efficacy limited by nothing but the smallness of 
 the difference between the two threads. 
 
 This principle was first applied in the manner represented 
 hi Jig. 142. A is the greater thread, playing in the fixed 
 nut; B is the lesser thread, cut upon a smaller cylinder, and 
 playing in a concave screw, cut within the greater cylinder. 
 During every revolution of the screw, the cylinder A de- 
 scends through a space equal to the distance between its 
 threads. At the same time the smaller cylinder B ascends 
 through a space equal to the distance between the threads 
 cut upon it : the effect is, that the board D descends through 
 a space equal to the difference between the threads upon A 
 and the threads upon B, and the machine has a power pro- 
 portionate to the smallness of this difference. 
 
 Thus, suppose the screw A has twenty threads in an inch, 
 while the screw B has twenty-one; during one revolution, 
 the screw A will descend through a space equal to the 20th 
 part of an inch. If, during this motion, the screw B did not 
 turn within A, the board D would be advanced through the 
 20th of an inch ; but because the hollow screw within A 
 turns upon B, the screw B will, relatively to A, be raised in 
 one revolution through a space equal to the 21st part of an 
 inch. Thus, while the board D is depressed through the 20th 
 of an inch by the screw A, it is raised through the 21st of 
 an inch by the screw B. It is, therefore, on the whole, de- 
 pressed through a space equal to the excess of the 0th ot 
 an inch above the 21st of an inch, that is, through the 420th 
 of an inch. 
 
 The power of this machine will, therefore, be expressed by 
 
CHAP. xvi. HUNTER'S SCREW. 187 
 
 the number of times the 420th of an inch is contained in 
 the circumference through which the power moves. 
 
 (298.) In the practical application of this principle at 
 present, the arrangement is somewhat different. The two 
 threads are usually cut on different parts of the same cylinder. 
 If nuts be supposed to be placed upon these, which are capa- 
 ble of moving in the direction of the length, but not of re- 
 volving, it is evident that by turning the screw once round, 
 each nut will be advanced through a space equal to the 
 breadth of the respective threads. By this means the two 
 nuts will either approach each other, or mutually recede, ac- 
 cording to the direction in which the screw is turned, through 
 a space equal to the difference of the breadth of the threads, 
 and they will exert a force either in compressing or extending 
 any substance placed between them, proportionate to the 
 smallness of that difference. 
 
 (299.) A toothed wheel is sometimes used instead of a nut, 
 so that the same quality by which the revolution of the 
 screw urges the nut forward is applied to make the wheel 
 revolve. The screw is in this case called an endless screw, 
 because its action upon the wheel may be continued without 
 limit. This application of the screw is represented in 
 Jig. 143. P is the winch to which the power is applied ; 
 and its effect at the circumference of the wheel is estimated 
 in the same manner as the effect of the screw upon the nut. 
 This effect is to be considered as a power acting upon the 
 circumference of the wheel ; and its proportion to the weight 
 or resistance is to be calculated in the same manner as the 
 oroportion of the power to the weight in the wheel and axle. 
 
 300. We have hitherto considered the screw as an engine 
 used to overcome great resistances. It is also eminently 
 useful in several departments of experimental science, for 
 the measurement of very minute motions and spaces, the 
 magnitude of which could scarcely be ascertained by any 
 other means. The very slow motion which may be imparted 
 to the end of a screw, by a very considerable motion in the 
 power, renders it peculiarly well adapted for this purpose. 
 To explain the manner in which it is applied suppose a 
 screw to be so cut as to have fifty threads in an inch, each 
 revolution of the screw will advance its point through the 
 fiftieth part of an inch. Now, suppose the head of the 
 screw to be a circle, whose diameter is an inch, the circum- 
 ference of the head will be something more than three inches : 
 
188 THE .ELEMENTS OF MECHANICS. CHAP. XVI. 
 
 this may be easily divided into a hundred equal parts distinct- 
 ly visible. If a fixed index be presented to this graduated 
 circumference, the hundredth part of a revolution of the 
 screw may be observed, by noting the passage of one division 
 of the head under the index. Since one entire revolution 
 of the head moves the point through the fiftieth of an inch, 
 one division will correspond to the five thousandth of an inch. 
 In order to observe the motion of the point of the screw in 
 this case, a fine wire is attached to it, which is carried across 
 the field of view of a powerful microscope, by which the mo- 
 tion is so magnified as to be distinctly perceptible. 
 
 A screw used for such purposes is called a micrometer 
 screw. Such an apparatus is usually attached to the limbs of 
 graduated instruments, for the purposes of astronomical and 
 other observation. Without the aid of this apparatus, no 
 observation could be taken with greater accuracy than the 
 amount of the smallest div ision upon the limb. Thus, if an 
 instrument for measuring angles were divided into small 
 arches of one minute, and an angle were observed which 
 brought the index of the instrument to some point between 
 two divisions, we could only conclude that the observed 
 angle must consist of a certain number of degrees and 
 minutes, together with an additional number of seconds, 
 which would be unknown, inasmuch as there would be no 
 means of ascertaining the fraction of a minute between the 
 index and the adjacent division of the instrument. But if a 
 screw be provided, the point of which moves through a space 
 equal to one division of the instrument, with sixty revolu- 
 tions of the head, and the head itself be divided into one 
 hundred equal parts, each complete revolution of the screw 
 will correspond to the sixtieth part of a minute, or to one 
 second, and each division on the head of the screw will cor- 
 respond to the hundredth part of a second. The index being 
 attached to this screw, let the head be turned until the index 
 be moved from its observed position to the adjacent division 
 of the limb. The number of complete revolutions of the 
 screw necessary to accomplish this will be the number of 
 seconds : and the number of parts of a revolution over the 
 complete number of revolutions will be the hundredth parts 
 of a second necessary to be added to the degrees and minutes 
 primarily observed. 
 
 It is not, however, only to angular instruments that the 
 micrometer screw is applicable ; any spaces whatever may be 
 
CHAP. XVII. REGULATION OF MACHINES. 189 
 
 measured by it. An instance of its mechanical application 
 may be mentioned in a steel-yard, an instrument for ascer- 
 taining the amount of weights by a given weight, sliding on 
 a long graduated arm of a lever. The distance from the 
 fulcrum, at which this weight counterpoises the weight to be 
 ascertained, serves as a measure to the amount of that weight. 
 When the sliding weight happens to be placed between two 
 divisions of the arm, a micrometer screw is used to ascertain 
 the fraction of the division. 
 
 Hunter's screw, already described, seems to be well adapt- 
 ed to micrometrical purposes ; since the motion of the point 
 may be rendered indefinitely slow, without requiring an ex- 
 quisitely fine thread, such as, in the single screw, would in 
 this case be necessary. 
 
 CHAPTER XVII. 
 
 ON THE REGULATION AND ACCUMULATION OF FORCE. 
 
 (301.) IT is frequently indispensable, and always desirable, 
 that the operation of a machine should be regular and uni- 
 form. Sudden changes in its velocity, and desultory varia- 
 tions in the effective energy of its power, are often injurious 
 or destructive to the apparatus itself, and when applied to 
 manufactures, never fail to produce unevenness in the work. 
 To invent methods for insuring the regular motion of ma- 
 chinery, by removing those causes of inequality which may 
 be avoided, and by compensating others, has therefore been 
 a problem to which much attention and ingenuity have been 
 directed. This is chiefly accomplished by controlling, and, 
 as it were, measuring out, the power according to the exi- 
 gencies of the machine, and causing its effective energy to 
 be always commensurate with the resistance which it has to 
 overcome. 
 
 Irregularity in the motion of machinery may proceed from 
 one or more of the following causes : 1. irregularity in the 
 prime mover ; 2. occasional variation in the amount of the 
 load or resistance ; and, 3. because, in the various positions 
 which the parts of the machine assume during its motion, 
 the power may not be transmitted with equal effect to the 
 working point. 
 
190 THE ELEMENTS OF MECHANICS. CHAP. XVII. 
 
 The energy of the prime mover is seldom, if ever^ regular. 
 The force of water varies with the copiousness of the stream. 
 The power which impels the windmill is proverbially capri- 
 cious. The pressure of steam varies with the intensity of 
 the furnace. Animal power, the result of will, temper, and 
 health, is difficult of control. -Human labor is most of all 
 unmanageable ; and no machine works so irregularly as one 
 which is manipulated. In some cases, the moving force is 
 subject, by the very conditions of its existence, to constant 
 variation, as in the example of a spring, which gradually 
 loses its energy as it recoils. (255). In many instances, the 
 prime mover is liable to regular intermission, and is actually 
 suspended for certain intervals of time. This is the case in 
 the single acting steam-engine, where the pressure of the 
 steam urges the descent of the piston, but is suspended dur- 
 ing its ascent. 
 
 The load or resistance to which the machine is applied 
 is not less fluctuating. In mills, there are a multiplicity of 
 parts which are severally liable to be occasionally disengaged, 
 and to have their operation suspended. In large factories 
 for spinning, weaving, printing, &,c., a great number of sepa- 
 rate spinning machines, looms, presses, or other engines, are 
 usually worked by one common mover, such as a water-wheel 
 or steam-engine. In these cases, the number of machines 
 employed from time to time necessarily varies with the fluc- 
 tuating demand for the articles produced, and from other 
 causes. Under such circumstances, the velocity with which 
 every part of the machinery is moved would suffer corre- 
 sponding changes, increasing its rapidity with every augmenta- 
 tion of the moving power or diminution of the resistance, or 
 being retarded in its speed by the contrary circumstances. 
 
 But even when the prime mover and the resistance are 
 both regular, or rendered so by proper contrivances, still it 
 will rarely happen that the machine by which the energy of 
 the one is transmitted to the other conveys this with unim- 
 paired effect in all the phases of its operation. To give a 
 general notion of this cause of inequality, to those who have 
 not been familiar with machinery, would not be easy, without 
 having recourse to an example. For the present we shall 
 merely state, that the several moving parts of every machine 
 assume in succession a variety of positions ; that at regular 
 periods they return to their first position, and again undergo 
 the same succession of changes. In the different positions 
 
CHAP. XVII. REGULATORS. GOVERNOR. 191 
 
 through which they are carried in every period of motion, the 
 efficacy of the machine to transmit the power to the resist- 
 ance is different, and thus the effective energy of the ma- 
 chine in acting upon the resistance would be subject to con- 
 tinual fluctuation. This will be more clearly understood 
 when we come to explain the methods of counteracting the 
 defect or equalizing the action of the power upon the re- 
 sistance. 
 
 Such are the chief causes of the inequalities incidental 
 to the motion of machinery, and we now propose to describe 
 a few of the many ingenious contrivances which the skill 
 of engineers has produced to remove the consequent incon- 
 veniences. 
 
 (302.) Setting aside, for the present, the last cause of ine- 
 quality, and considering the machinery, whatever it be, to 
 transmit the power to the resistance without irregular inter- 
 ruption, it is evident that every contrivance, having for its 
 object to render the velocity uniform, can only accomplish 
 this by causing the variations of the power and resistance to 
 be proportionate to each other. This may be done either 
 by increasing or diminishing the power as the resistance 
 increases or diminishes ; or by increasing or diminishing the 
 resistance as the power increases or diminishes ; and accord- 
 ing to the facilities or convenience presented by the pecu- 
 liar circumstances of the case, either of these methods is 
 adopted. 
 
 The contrivances for effecting this are called regulators, 
 Most regulators act upon that part of the machine which 
 commands the supply of the power by means of levers, or 
 some other mechanical contrivance, so as to check the quan- 
 tity of the moving principle conveyed to the machine when 
 the velocity has a tendency to increase j and, on the other 
 hand, to increase that supply upon any undue abatement of 
 its speed. In a water-mill this is done by acting upon the 
 shuttle ; in a wind-mill, by an adjustment of the sail-cloth ; 
 and in a steam-engine, by opening or closing, in a greater or 
 less degree, the valve by which the cylinder is supplied with 
 steam. 
 
 (303.) Of all the contrivances for regulating machinery, 
 that which is best known and most commonly used is the 
 governor. This regulator, which had been long in use in 
 mill-work and other machinery, has of late years attracted 
 more general notice by its beautiful adaptation in the steam- 
 
192 THE ELEMENTS OF MECHANICS. CHAP. XVII. 
 
 engines of Watt. It consists of heavy balls B B, Jig. 144., 
 attached to the extremities of rods B F. These rods play 
 upon a joint at E, passing through a mortise in the vertical 
 stem D D'. At F they are united by joints to the short rods 
 F H, which are again connected by joints at H to a ring 
 which slides upon the vertical shaft D D'. From this de- 
 scription it will be apparent that when the balls B are drawn 
 from the axis, their upper arms E F are caused to increase 
 their divergence in the same manner as the blades of scis- 
 sors are opened by separating the handles. These, acting 
 upon the ring by means of the short links F H, draw it down 
 the vertical axis from D towards E. A contrary effect is pro- 
 duced when the balls B are brought closer to the axis, and 
 the divergence of the rods B E diminished. A horizontal 
 wheel W is attached to the vertical axis D D', having a 
 groove to receive a rope or strap upon its rim. This strap 
 passes round the wheel or axis by which motion is transmit- 
 ted to the machinery to be regulated, so that the spindle or 
 shaft D D' will always be made to revolve with a speed pro- 
 portionate to that of the machinery. 
 
 As the shaft D D' revolves, the balls B are carried round 
 it with a circular motion, and consequently acquire a centrifu- 
 gal force, which causes them to recede from the axle, and 
 therefore to depress the ring H. On the edge or rim of this 
 ring is formed a groove, which is embraced by the prongs 
 of a fork I, at the extremity of one arm of a lever whose 
 fulcrum is at G. The extremity K of the other arm is con- 
 nected by some means with the part of the machine which 
 supplies the power. In the present instance, we shall sup- 
 pose it a steam-engine, in which case the rod K I communicates 
 with a flat circular valve V, placed in the principal steam- 
 pipe, and so arranged that, when K is elevated as far as by 
 their divergence the balls B have power over it, the passage 
 of the pipe will be closed by the valve V, and the passage of 
 steam entirely stopped ; and on the other hand, when the 
 balls subside to their 'lowest position, the valve will be pre- 
 sented with its edge in the direction of the tube, so as to 
 intercept no part of the steam. 
 
 The property which renders this instrument so admirably 
 adapted to the purpose to which it is applied is, that when 
 the divergence of the balls is not very considerable, they 
 must always revolve with the same velocity, whether they 
 move at a greater or lesser distance from the vertical axis 
 
CHAP. XVII. WATER-REGULATOR. 193 
 
 If any circumstance increases that velocity, the balls instantly 
 recede from the axis, and, closing the valve V, check the sup- 
 ply of steam, arid thereby, diminishing the speed of the motion, 
 restore the machine to its former rate. If, on the contrary, 
 that fixed velocity be diminished, the centrifugal force being 
 no longer sufficient to support the balls, they descend towards 
 the axle, open the valve V, and, increasing the supply of steam, 
 restore the proper velocity of the machine. 
 
 When the governor is applied to a water-wheel, it is made 
 to act upon the shuttle through which the water flows, and 
 controls its quantity as effectually, and upon the same prin- 
 ciple, as has just been explained in reference to the steam- 
 engine. When applied to a wind-mill, it regulates the sail- 
 cloth so as to diminish the efficacy of the power upon the 
 arms as the force of the wind increases, or vice versa. 
 
 In cases where the resistance admits of easy and conve- 
 nient change, the governor may act so as to accommodate it to 
 the varying energy of the power. This is often done in corn- 
 mills, where it acts upon the shuttle which metes out the 
 corn to the millstones. When the power which drives the 
 mill increases, a proportionally increased feed of corn is given 
 to the stones, so that, the resistance being varied in the ratio 
 of the power, the same velocity will be maintained. 
 
 (304.) In some cases, the centrifugal force of the revolving 
 balls is not sufficiently great to control the power or the re- 
 sistance, and regulators of a different kind must be resorted 
 to. The following contrivance is called the water-regula- 
 tor : 
 
 A common pump is worked by the machine, whose motion 
 is to be regulated, and water is thus raised and discharged 
 into a cistern. It is allowed to flow from this cistern through 
 a pipe of a given magnitude. When the x water is pumped 
 up with the same velocity as it is discharged by this pipe, it 
 is evident that the level of the water in the cistern will be 
 stationary, since it receives from the pump the exact quantity 
 which it discharges from the pipe. But if the pump throw 
 in more water in a given time than is discharged by the pipe, 
 the cistern will begin to be filled, and the level of the water 
 will rise. If, on the other hand, the supply from the pump 
 be less than the discharge from the pipe, the level of the 
 water in the cistern will subside. Since the rate at which 
 water is supplied from the pump will always be proportional 
 to the velocity of the machine, it follows that every fluctua- 
 17 
 
194 THE ELEMENTS OP MECHANICS. CHAP. XVII. 
 
 tion in this velocity will be indicated by the rising or sub- 
 siding of the level of the water in the cistern, and that level 
 never can remain stationary, except at that exact velocity 
 which supplies the quantity of water discharged by the pipe. 
 This pipe may be constructed so as by an adjustment to dis r 
 charge the water at any required rate ; and thus the cistern 
 may be adapted to indicate a constant velocity of any pro r 
 posed amount. 
 
 If the cistern were constantly watched by an attendant^ 
 the velocity of the machine might be abated by regulating 
 the power when the level of the water is observed to rise, 
 or increased when it falls ; but this is much more effectually 
 and regularly performed by causing the surface of th.e water 
 itself to perform the duty. A float or large hollow metal 
 ball is placed upon the surface of the water in the cistern. 
 This ball is connected with a lever acting upon some part 
 of the machinery, which controls the power or regulates the 
 amount of resistance, as already explained in the case of 
 the governor. When the level of the water rises, the buoy- 
 ancy of the ball causes it to rise also with a force equal 
 to the difference between its own weight and the weight of 
 as much water as it displaces. By enlarging the floating 
 ball, a force may be obtained sufficiently great to move those 
 parts of the machinery which act upon the power or resist- 
 ance, and thus either to diminish the supply of the moving 
 principle, or to increase the amount of the resistance, and 
 thereby retard the motion and reduce the velocity to its 
 proper limit. When the level of the water in the cistern 
 falls, the floating ball, being no longer supported on the 
 liquid surface, descends with the force of its own weight, 
 and, producing an effect upon the power or resistance contrary 
 to the former, increases the effective energy of the one, or 
 diminishes that of the other, until the velocity proper to the 
 machine be restored. 
 
 The sensibility of these regulators is increased by making 
 the surface of water in the cistern as small as possible ; for 
 then a small change in the rate at which the water is supplied 
 by the pump will produce a considerable change in the level 
 of the water in the cistern. 
 
 Instead of using a float, the cistern itself may be suspend- 
 ed from the lever which controls the supply of the power, 
 and in this case a sliding weight may be placed on the other 
 arm, so that it will balance the cylinder when it contains that 
 
CHAP. XVII. 
 
 REGULATORS. 195 
 
 quantity of water which corresponds to the fixed level already 
 explained. If the quantity of water in the cistern be in- 
 creased by an undue velocity of the machine, the weight of 
 the cistern will preponderate, draw down the arm of the lever, 
 and check the supply of the power. If, on the other hand, 
 the supply of water be too small, the cistern will no longer 
 balance the counterpoise, the arm by which it is suspended 
 will be raised, and the energy of the power will be increased. 
 
 (305.) In the steam-engine, the self-regulating principle is 
 carried to an astonishing pitch of perfection. The machine 
 itself raises in a due quantity the cold water necessary to 
 condense the steam. It pumps off the hot water produced by 
 the steam, which has been cooled, and lodges it in a reservoir 
 for the supply of the boiler. It carries from this reservoir 
 exactly that quantity of water which is necessary to supply 
 the wants of the boiler, and lodges it therein according as it 
 is required. It breathes the boiler of redundant steam, and 
 preserves that which remains fit, both in quantity and quality, 
 for the use of the engine. It blows its own fire, maintaining 
 its intensity, and increasing or diminishing it according to 
 the quantity of steam which it is necessary to raise ; so that 
 when much work is expected from the engine, the fire is 
 proportionally brisk and vivid. It breaks and prepares its 
 own fuel, and scatters it upon the bars at proper times and 
 in due quantity. It opens and closes its several valves at the 
 proper moments, works its own pumps, turns its own wheels, 
 and is only not alive. Among so many beautiful examples 
 of the self-regulating principle, it is difficult to select. We 
 shall, however, mention one or two, and for others refer the 
 reader to that part of the Cyclopaedia which will contain a 
 detailed description of the steam-engine itself. 
 
 It is necessary in this machine that the water in the boiler 
 be maintained constantly at the same level, and, therefore, 
 that as much be supplied, from time to time, as is consumed 
 by evaporation. A pump, which is wrought by the engine 
 itself, supplies a cistern C,.$b r - 145., with hot water. At the 
 bottom of this cistern is a valve V opening into a tube which 
 descends into the boiler. This valve is connected by a wire 
 with the arm of a lever on the fulcrum D, the other arm E 
 of which is also connected by a wire with a stone float F, 
 which is partially immersed in the water of the boiler, and is 
 balanced by a sliding weight A. The weight A only coun- 
 terpoises the stone float F by the aid of its buoyance in the 
 
 
196 THE ELEMENTS OF MECHANICS CHAP. XVII. 
 
 water ; for if the water be removed, the stone F will prepon- 
 derate, and raise the weight A. When the water in the 
 boiler is at its proper level, the length of the wire connecting 
 the valve V with the lever is so adjusted that this valve shall 
 be closed, the wire at the same time being fully extended. 
 When, by evaporation, the water in the boiler begins to be 
 diminished, the level falls, and the stone weight F, being no 
 longer supported, overcomes the counterpoise A, raises the 
 arm of the lever, and, pulling the wire, opens the valve V. 
 The water in the cistern C then flows through the tube into 
 the boiler, and continues to flow until the level be so raised 
 that the stone weight F is again elevated, the valve V closed, 
 and the further supply of water from the cistern C suspended. 
 
 In order to render the operation of this apparatus easily 
 intelligible, we have here supposed an imperfection which 
 does not exist. According to what has just been stated, the 
 level of the water in the boiler descends from its proper 
 height, and subsequently returns to it. But, in fact, this 
 does not happen. The float F and valve V adjust themselves, 
 so that a constant supply of water passes through the valve, 
 which proceeds exactly at the same rate as that at which the 
 crater in the boiler is consumed. 
 
 (306.) In the same machine there occurs a singularly hap- 
 py example of self-adjustment, in the method by which the 
 strength of the fire is regulated. The governor regulates the 
 supply of steam to the engine, and proportions it to the work 
 to be done. With this work, therefore, the demands upon 
 the boiler increase or diminish, and with these demands the 
 production of steam in the boiler ought to vary. In fact, the 
 rate at which steam is generated in the boiler ought to be 
 equal to that at which it is consumed in the engine, other- 
 wise one of two effects must ensue : either the boiler will 
 fail to supply the engine with steam, or steam will accumulate 
 n the boiler, being produced in undue quantity, and, escaping 
 at the safety valve, will thus be wasted. It is, therefore > 
 necessary to control the agent which generates the steam, 
 namely, the fire, and to vary its intensity from time to time, 
 proportioning it to the demands of the engine. To accom- 
 plish this, the following contrivance has been adopted : Let 
 T,Jig. 146., be a tube inserted in the top of the boiler, and 
 descending nearly to the bottom. The pressure of the steam 
 confined in the boiler, acting upon the surface of the water, 
 forces it to a certain height in the tube T. A weight F, 
 
CHAP. XVII. TACHOMETER. 197 
 
 half immersed in the water in the tube, is suspended by a 
 chain, which passes over the wheels P 1*', and is balanced 
 by a metal plate D, in the same manner as the stone float, 
 fig. 145., is balanced by the weight A. The plate D passes 
 through the mouth of the flue E as it issues finally from the 
 boiler : so that when the plate D falls, it stops the flue, sus- 
 pending thereby the draught of air through the furnace, 
 mitigating the intensity of the fire, and checking the produc- 
 tion of steam. If, on the contrary, the plate D be drawn up 
 the draught, is increased, the fire is rendered more active, 
 and the production of steam in the boiler is stimulated. 
 Now, suppose that the boiler produces steam faster than the 
 engine consumes it, either because the load on the engine 
 lias been diminished, and, therefore, its consumption of 
 steam reduced, or because the fire has become too intense ; 
 the consequence is, that the steam, beginning to accumulate 
 in the boiler, will press upon the surface of the water with 
 increased force, and the water will be raised in the tube T. 
 The weight F will, therefore, be lifted, arid the plate D will 
 descend, diminish, or stop the draught, mitigate the fire, and 
 retard the production of steam, and will continue to do so 
 until the rate at which steam is produced shall be commen- 
 surate to the wants of the engine. 
 
 If, on the other hand, the production of steam be inade- 
 quate to the exigency of the machine, either because of an 
 increased load, or of the insufficient force of the fire, the 
 steam in the boiler will lose its elasticity, and the surface of 
 the water not sustaining its wonted pressure, the water in the 
 tube T will fall ; consequently the weight F will descend, 
 and the plate D will be raised. The flue being thus opened, 
 the draught will be increased, and the fire rendered more in- 
 tense. Thus the production of steam becomes more rapid, 
 and is rendered sufficiently abundant for the purposes of the 
 engine. This apparatus is called the self-acting damper. 
 
 (307.) When a perfectly uniform rate of motion has not 
 been attained, it is often necessary to indicate small varia- 
 tions of velocity. The following contrivance, called a ta- 
 chometer* has been invented to accomplish this. A cup, 
 Jig. 147., is filled to the level C D with quicksilver, and is 
 attached to a spindle, which is whirled by the machine in the 
 same manner as the governor already described. It is well 
 
 From the Greek words tachos, sj>eed ; and metron, measure. 
 
198 THE ELEMENTS OF MECHANICS. CHAP. XVII. 
 
 known that the centrifugal force, produced by this whirling 
 motion, will cause the mercury to recede from the centre, and 
 rise upon the sides of the cup, so that its surface will assume 
 the concave appearance represented in fg. 148. In this 
 case, the centre of the surface will ohviously have fallen be- 
 low its original level,///,''. 147., and the edges will have risen 
 above that level. As this effect is produced by the velocity 
 of the machine, so it is proportionate to that velocity, and 
 subject to corresponding variations. Any method of render- 
 ing visible small changes in the central level of the surface 
 of the quicksilver will indicate minute variations in the ve- 
 locity of the machine. 
 
 A glass tube A, open at both ends, and expanding at one 
 extremity into a beil B, is immersed with its wider end in the 
 mercury, the surface of which will stand at the same level 
 in the bell B, and in the cup C D. The tube is so suspended 
 as to be unconnected with the cup. This tube is then filled 
 to a certain height A, with spirits tinged with some coloring 
 matter, to render it easily observable. When the cup is whirl- 
 ed by the machine to which it is attached, the level of the 
 quicksilver in the bell falls, leaving more space for the spirits, 
 which, therefore, descend in the tube. As the motion is 
 continued, every change of velocity causes a corresponding 
 change in the level of the mercury, and, therefore, also in 
 the level A of the spirits. It will be observed, that, in con- 
 sequence of the capacity of the bell B being much greater 
 than that of the tube A, a very small change in the level of 
 the quicksilver in the bell will produce a considerable change 
 in the height of the spirits in the tube. Thus this ingenious 
 instrument becomes a very delicate indicator of variations in 
 the motion of machinery. 
 
 (808.) The governor, and other methods of regulating the 
 motion of machinery which have been just described, are 
 adapted principally to cases in which the proportion of the 
 resistance to the load is subject to certain fluctuations or 
 gradual changes, or at least to cases in which the resistance 
 is not at any time entirely withdrawn, nor the energy of the 
 power actually suspended. Circumstances, however, frequent- 
 ly occur in which, while the power remains in full activity, 
 the resistance is at intervals suddenly removed, and as 
 suddenly again returns. On the other hand, cases also pre- 
 sent themselves, in which, while the resistance is continued, 
 the impelling power is subject to intermission at regular pe- 
 
UHAP. XVII. ACCUMULATION OF FORCE. 199 
 
 riods. In the former case, the machine would be driven 
 with a ruinous rapidity during those periods at which it is 
 relieved from its load, and, on the return of the load, every 
 part would suffer a violent strain, from its endeavor to re- 
 tain the velocity which it had acquired, and the speedy de- 
 struction of the engine could not fail to ensue. In the 
 latter case, the motion would be greatly retarded or entirely 
 suspended during those periods at which the moving power 
 is deprived of its activity, and, consequently, the motion which 
 it would communicate would be so irregular as to be useless 
 for the purposes of manufactures. 
 
 It is also frequently desirable, by means of a weak but 
 continued power, to produce a severe but instantaneous effect. 
 Thus a blow may be required to be given by the muscular 
 action of a man's arm with a force to which, unaided by 
 mechanical contrivance, its strength would be entirely in- 
 adequate. 
 
 In all these cases, it is evident that the object to be at- 
 tained is, an effectual method of accumulating the energy of 
 the power, so as to make it available after the action by which 
 it has been produced has ceased. Thus, in the case in which 
 the load is at periodical intervals withdrawn from the machine, 
 if the force of the power could be imparted to something by 
 which it would be preserved, so as to be brought against the 
 load when it again returned, the inconvenience would be 
 removed. In like manner, in the case where the power 
 itself is subject to intermission, if a part of the force which it 
 exerts in its intervals of action could be accumulated and 
 preserved, it might be brought to bear upon the machine 
 during its periods of suspension. By the same means of ac- 
 cumulating force, the strength of an infant, by repeated 
 efforts, might produce effects which would be vainly attempt- 
 ed by the single and momentary action of the strongest man. 
 
 (309.) The property of inertia, explained and illustrated 
 in the third and fourth chapters of this volume, furnishes an 
 easy and effectual method of accomplishing this. A mass 
 of matter retains, by virtue of its inertia, the whole of any 
 force which may have been given to it, except that part of 
 which friction and the atmospheric resistance deprive it. 
 By contrivances which are well known, and present no diffi- 
 culty, the part of the moving force thus lost may be rendered 
 comparatively small, and the moving mass rnay be regarded 
 as retaining nearly the whole of the force impressed upon it. 
 
200 THE ELEMENTS OF MECHANICS. CHAP. XVII. 
 
 To render this method of accumulating force fully intelligi- 
 ble, let us first imagine a polished level plane on which a 
 heavy globe of metal, also polished, is placed. It is evident 
 that the globe will remain at rest on any part of the plane 
 without a tendency to move in any direction. As the friction 
 is nearly removed by the polish of the surfaces, the globe 
 will be easily moved by the least force applied to it. Sup- 
 pose a slight impulse given to it, which will cause it to move 
 at the rate of one foot in a second. Setting aside the effects 
 of friction, it will continue to move at this rate for any length 
 of time. The same impulse repeated will increase its speed 
 to two feet per second; a third impulse to three feet; and so 
 on. Thus 10,000 repetitions of the impulse will cause it 
 to move at the rate of 10,000 feet per second. If the body 
 to which these impulses were communicated were a cannon 
 ball, it might, by a constant repetition of the impelling force, 
 be at length made to move with as much force as if it were 
 projected from the most powerful piece of ordnance. The 
 force with which the ball in such a case would strike a build- 
 ing might be sufficient to reduce it to ruins, and yet such 
 force would be nothing more than the accumulation of a 
 number of weak efforts not beyond the power of a child to 
 exert, which are stored up, and preserved, as it were, by the 
 moving mass, and thereby brought to bear, at the same mo- 
 ment, upon the point to which the force is directed. It is 
 the sum of a number of actions exerted successively, and, 
 during a long interval, brought into operation at one and the 
 same moment. 
 
 But the case which is here supposed cannot actually occur ; 
 because we have not usually any practical means of moving 
 a body for any considerable time in the same direction with- 
 out much friction, and without encountering numerous ob- 
 stacles which would impede its progress. It is not, however, 
 essential to the effect which is to be produced, that the mo- 
 tion should be in a straight line. If a leaden weight be at- 
 tached to the end of a light rod or cord, and be whirled by 
 the force of the arm in a circle, it will gradually acquire in- 
 creased speed and force, and at length may receive an impetus 
 which would cause it to penetrate a piece of board as effect- 
 ually as if it were discharged from a musket. 
 
 The force of a hammer or sledge depends partly on its 
 weight, but much more on the principle just explained. Were 
 it allowed merely to fall by the force of its weight upon the 
 
CHAP. XVII. FLV-VVHEEL. 201 
 
 head of a nail, or upon a bar of heated iron which is to be 
 flattened, an inconsiderable effect would be produced. But 
 when it is wielded by the arm of a man, it receives at every 
 moment of its motion increased force, which is finally ex- 
 pended in a single instant on the head of the nail, or on the 
 bar of iron. 
 
 The effects of flails in threshing, of clubs, whips, canes, 
 and instruments for striking, axes, hatchets, cleavers, and all 
 instruments which cut by a blow, depend on the same prin- 
 ciple, and are similarly explained. 
 
 The bow-string which impels the arrow does not produce 
 its effect at once. It continues to act upon the shaft until it 
 resumes its straight position, and then the arrow takes flight 
 with the force accumulated during the continuance of the 
 action of the string, from the moment it was disengaged from 
 the finger of the bow-man. 
 
 Fire-arms themselves act upon a similar principle, as also 
 the air-gun and steam-gun. In these instruments, the ball 
 is placed in a tube, and suddenly exposed to the pressure of 
 a highly elastic fluid, either produced by explosion as in fire- 
 arms, by previous condensation as in the air-gun, or by the 
 evaporation of highly heated liquids as in the steam-gun. 
 But in every case this pressure continues to act upon it until 
 it leaves the mouth of the tube, and then it departs with the 
 whole force communicated to it during its passage along the 
 tube. 
 
 (310.) From all these considerations it will easily be per- 
 ceived that a mass of inert matter may be regarded as a 
 magazine in which force may be deposited and accumulated, 
 to be used in any way which may be necessary. For many 
 reasons, which will be sufficiently obvious, the form common- 
 ly given to the mass of matter used for this purpose in ma- 
 chinery, is that of a wheel, in the rim of which it is principal- 
 ly collected. Conceive a massive ring of metal, Jig. 149., 
 connected with a central box or nave by light spokes, and 
 turning on an axis with little friction. Such an apparatus is 
 called a fly-wheel. If any force be applied to it, with that 
 force (making some slight deduction for friction) it will move, 
 and will continue to move until some obstacle be opposed to 
 its motion, which will receive from it a part of the force it 
 has acquired. The uses of this apparatus will be easily un- 
 derstood by examples of its application. 
 
 Suppose that a heavy stamper or hammer is to be raised to 
 
202 THE ELEMENTS OF MECHANICS. CHAP. XVII. 
 
 a certain height, and thence to be allowed to fall, and that 
 the power used for this purpose is a water-wheel. While the 
 stamper ascends, the power of the wheel is nearly balanced 
 by its weight, and the motion of the machine is slow. But 
 the moment the stamper is disengaged and allowed to fall, the 
 power of the wheel, having no resistance, nor any object on 
 which to expend itself, suddenly accelerates the machine, 
 which moves with a speed proportioned to the amount of the 
 power, until it again engages the stamper, when its velocity 
 is as suddenly checked. Every part suffers a strain, and the 
 machine moves again slowly until it discharges its load, when 
 it is again accelerated, and so on. In this case, besides the 
 certainty of injury and wear, and the probability of fracture 
 from the sudden and frequent changes of velocity, nearly the 
 whole force exerted by the power in the intervals between the 
 commencement of each descent of the stamper and the next 
 ascent, is lost. These defects are removed by a fly-wheel. 
 When the stamper is discharged, the energy of the power is 
 expended in moving the wheel, which, by reason of its great 
 mass, will not receive an undue velocity. In the interval be- 
 tween the descent and ascent of the stamper, the force of 
 the power is lodged in the heavy rim of the fly-wheel. When 
 the stamper is again taken up by the machine, this force is 
 brought to bear upon it, combined with the immediate power 
 of the water-wheel, and the stamper is elevated with nearly 
 the same velocity as that with which the machine moved in 
 the interval of its descent. 
 
 (311.) In many cases, when the moving power is not sub- 
 ject to variation, the efficacy of the machine to transmit it 
 to the working point is subject to continual change. The 
 several parts of every machine have certain periods of motion, 
 in which they pass through a variety of positions, to which 
 they continually return after stated intervals. In these differ- 
 ent positions, the effect of the power transmitted to the work- 
 ing point is different ; and cases even occur in which this ef- 
 fect is altogether annihilated, and the machine is brought into 
 a predicament in which the power loses all influence over the 
 weight. In such cases, the aid of a fly-wheel is effectual and 
 indispensable. In those phases of the machine, which are 
 most favorable to the transmission of force, the fly-wheel 
 shares the effect of the power with the load, and, retaining the 
 force thus received, directs it upon the load at the moments 
 when the transmission of power by the machine is either fee 
 
CHAP. XVII. FLY-WHEEL AND CRANK. 203 
 
 ble or altogether suspended. These general observations 
 will, perhaps, be more clearly apprehended by an example of 
 an application of the fly-wheel, in a case such as those now 
 alluded to. 
 
 Let A B C D E F,fg. 150., be a crank, which is a double 
 winch ( (252.) and Jig. 89.), by which an axle, A B E F, is 
 ,to be turned. Attached to the middle of C D by a joint is a 
 rod, which is connected with a beam, worked with an alter- 
 jiate motion on a centre, like the brake of a pump, and driven 
 joy any constant power, such as a steam-engine. The bar 
 G D is to be carried with a circular motion round the axis 
 4- E. Let the machine, viewed in the direction A B E F of 
 the axis, be conceived to be represented in fig. 151., where 
 A represents the centre round which the motion is to be pro- 
 duced, and G the point where the connecting rod G H is at- 
 tached to the arm of the crank. The circle through which 
 G is to be urged by the rod is represented by the dotted line. 
 In the position represented in jig. 151., the rod acting in the 
 direction H G has its full power to turn the crank G A round 
 the centre A. As the crank comes into the position repre- 
 sented in Jig. 152., this power is diminished, and when the 
 point G comes immediately below A, as in Jig. 153., the force 
 in the direction H G has no effect in turning the crank round 
 A, but, on the contrary, is entirely expended in pulling the 
 crank in the direction A G, and, therefore, only acts upon the 
 pivots or gudgeons which support the axle. At this crisis of 
 the motion, therefore, the whole effective energy of the power 
 is annihilated. 
 
 After the crank has passed to the position represented in 
 Jig. 154., the direction of the force which acts upon the con- 
 necting rod is changed, and now the crank is drawn upward 
 in the direction G H. In this position, the moving force has 
 some efficacy to produce rotation round A, which efficacy 
 continually increases until the crank attains the position shown 
 in Jig. 155., when its power is greatest. Passing from this 
 position, its efficacy is continually diminished, until the point 
 G comes immediately above the axis A, Jig. 156. Here again 
 the power loses all its efficacy to turn the axle. The force 
 in the direction G H or H G can obviously produce no other 
 effect than a strain upon the pivots or gudgeons. 
 
 In the critical situations represented in Jig. 153. and fig. 
 156., the machine would be incapable of moving, were the 
 immediate force of the power the only impelling principle 
 
204 THE ELEMENTS OF MECHANICS. CHAP. XVII. 
 
 But, having been previously in motion by virtue of the inertia 
 of its various parts, it has a tendency to continue in motion ; 
 and if the resistance of the load and the effects oi iriction be 
 not too great, this disposition to preserve its state of motion 
 will extricate the machine from the dilemma in which it is in- 
 volved, in the cases just mentioned, by the peculiar arrange- 
 ment of its parts. In many cases, however, the force thus 
 acquired during the phases of the machine in which the pow- 
 er is active, is insufficient to carry it through the dead points 
 (fig- 153. and Jig. 156.); and in all cases, the motion would 
 be very unequal, being continually retarded as it approached 
 these points, and continually accelerated after it passed them. 
 A fly-wheel attached to the axis A, or to some other part of 
 the machinery, will effectually remove this defect. When 
 the crank assumes the positions in Jig. 151. andj#g\ 155., the 
 power is in full play upon it, and a share of the effect is im- 
 parted to the massive rim of the fly-wheel. When the crank 
 gets into the predicament exhibited \njig. 153. and jg\ 156., 
 the momentum, which the fly-wheel received when the crank 
 acted with most advantage, immediately extricates the ma- 
 chine, and, carrying the crank beyond the dead point, brings 
 the power again to bear upon it. 
 
 The astonishing effects of a fly-wheel, as an accumulator 
 of force, have led some into the error of supposing that such 
 an apparatus increases the actual power of a machine. It is 
 hoped, however, that after what has been explained respect- 
 ing the inertia of matter and the true effects of machines, the 
 reader will not be liable to a similar mistake. On the con- 
 trary, as a fly cannot act without friction, and as the amount 
 of the friction, like that of inertia, is in proportion to the 
 weight, a portion of the actual moving force must unavoida- 
 bly be lost by the use of a fly. In cases, however, where a 
 fly is properly applied, this loss of power is inconsiderable, 
 compared with the advantageous distribution of what re- 
 mains. 
 
 As an accumulator of force, a fly can never have more force 
 than has been applied to put it in motion. In this respect it 
 is analogous to an elastic spring, or the force of condensed 
 air, or any other power which derives its existence from causes 
 purely mechanical. In bending a spring, a gradual expendi- 
 ture of power is necessary. On the recoil, this power is ex- 
 erted in a much shorter time than that consumed in its pro- 
 duction, but its total amount is not altered. Air is condens- 
 
CHAP. XVII. FLY-WHEEL. 205 
 
 ed by a succession of manual efforts, one of which alone 
 would be incapable of projecting a leaden ball with any con- 
 siderable force, and all of which could not be immediately 
 applied to the ball at the same instant. But the reservoir of 
 condensed air is a magazine in which a great number of such 
 efforts are stored up, so as to be brought at once into action. 
 If a ball be exposed to their effect, it may be projected with 
 a destructive force. 
 
 In mills for rolling metal, the fly-wheel is used in this way. 
 The water-wheel or other moving power is allowed for some 
 time to act upon the fly-wheel alone, no load being placed 
 upon the machine. A force is thus gained which is sufficient 
 to roll a large piece of metal, to which without such means 
 the mill would be quite inadequate. In the same manner a 
 force may be gained by the arm of a man acting on a fly for 
 a few seconds, sufficient to impress an image on a piece of 
 metal by an instantaneous stroke. The fly is, therefore, the 
 principal agent in coining presses. 
 
 (312.) The power of a fly is often transmitted to the work- 
 ing point by means of a screw. At the extremities of the 
 cross arm A B, jig. 157., which works the screw, two heavy 
 balls of metal are placed. When the arm A B is whirled 
 round, those masses of metal acquire a momentum, by which 
 the screw, being driven downwards, urges the die with an im- 
 mense force against the substance destined to receive the im- 
 pression. 
 
 Some engines used in coining have flies with arms four feet 
 long, bearing one hundred weight at each of their extremities. 
 By turning such an arm at the rate of one entire circumfer- 
 ence in a second, the die will be driven against the metal with 
 the same force as that with which 7500 pounds weight would 
 fall from the height of 16 feet ; an enormous power, if the 
 simplicity and compactness of the machine be considered. 
 
 The place to be assigned to a fly-wheel relatively to the 
 other parts of the machinery is determined by the purpose for 
 which it is used. If it be intended to equalize the action, it 
 should be near the working point. Thus, in a steam-engine, 
 it is placed on the crank which turns the axle by which the 
 power of the engine is transmitted to the object it is finally 
 designed to affect. On the contrary, in handmills, such 
 as those commonly used for grinding coffee, &,c., it is 
 placed upon the axis of the winch by which the machine is 
 worked. 
 
 18 
 
206 THE ELEMENTS OF MECHANICS. CHAP. XVIII. 
 
 The open work of fenders, fire-grates, and similar orna- 
 mental articles constructed in metal, is produced by the action 
 of a fly, in the manner already described. The cutting tool, 
 shaped according to the pattern to be executed, is attached to 
 the end of the screw ; and the metal being held in a proper po- 
 sition beneath it, the fly is made to urge the tool downwards 
 with such force ag to stamp out pieces of the required figure. 
 When the pattern is complicated, and it is necessary to pre- 
 serve with exactness the relative situation of its different parts, 
 a number of punches are impelled together, so as to strike 
 the entire piece of metal at the same instant, and in this man- 
 ner the most elaborate open work is executed by a single stroke 
 of the hand, 
 
 CHAPTER XVIII 
 
 MECHANICAL CONTRIVANCES FOR MODIFYING MOTION. 
 
 313.) THE classes of simple machines denominated me- 
 chanic powers, have relation chiefly to the peculiar principle 
 which determines the action of the power on the weight or 
 resistance. In explaining this arrangement, various other 
 reflections have been incidentally mixed up with our investi- 
 gations : yet still much remains to be unfolded before the 
 student can form a just notion of those means, by which the 
 complex machinery used in the arts and manufactures so ef- 
 fectually attains the ends, to the accomplishment of which it 
 is directed, 
 
 By a power of a given energy to oppose a resistance of a 
 different energy, or by a moving principle having a given 
 velocity to generate another velocity of a different amount, is 
 only one of the many objects to be effected by a machine. In 
 the arts and manufactures, the kind of motion produced is gen- 
 erally of greater importance than its rate. The latter may ef- 
 fect the quantity of work done in a given time, but the former 
 is essential to the performance of the work in any quantity what- 
 ever. In the practical application of machines, the object to be 
 attained is generally to communicate to the working point some 
 peculiar sort of motion suitable to the uses for which the ma- 
 chine is intended ; but it rarely happens that the moving power 
 has this sort of motion. Hence the machine must be so con- 
 
CHAP. XVIII. MODIFICATION Of MOTION. 207 
 
 trived that, while that part on which this power acts is capa- 
 ble of moving in obedience to it, its connection with the 
 other parts shall be such that the working point may receive 
 that motion which is necessary for the purposes to which the 
 machine is applied. 
 
 To give a perfect solution of this problem, it would be 
 necessary to explain, first, all the varieties of moving powers 
 which are at our disposal ; secondly, all the variety of mo- 
 tions which it may be necessary to produce ; and, thirdly 
 to show all the methods by which each variety of prime 
 mover may be made to produce the several species of motion 
 in the working point. It is obvious that such an enumeration 
 would be impracticable, and even an approximation to it 
 would be unsuitable to the present treatise. Nevertheless, 
 so much ingenuity has been displayed in many of the con- 
 trivances for modifying motion, and an acquaintance with 
 some of them is so essential to a clear comprehension of the 
 nature and operation of complex machines, that it would be 
 improper to omit some account of those at least which most 
 frequently occur in machinery, or which are most conspicuous 
 for elegance and simplicity. 
 
 The varieties of motion which most commonly present 
 themselves in the practical application of mechanics may be 
 divided into rectilinear and rotatory. In rectilinear motion 
 the several parts of the moving body proceed in parallel 
 straight lines with the same speed. In rotatory motion the 
 several points revolve round an axis, each performing a com- 
 plete circle, or similar parts of a circle, in the same time. 
 
 Each of these may again be resolved into continued and 
 reciprocating. In a continued motion, whether rectilinear 
 or rotatory, the parts move constantly in the same direction, 
 whether that be in parallel straight lines, or in rotation on an 
 axis. In reciprocating motion the several parts move alter- 
 nately in opposite directions, tracing the same spaces from 
 end to end continually. Thus there are four principal species 
 of motion which more frequently than any others act upon, 
 or are required to be transmitted by, machines : 
 
 1. Continued rectilinear motion. 
 
 2. Reciprocating rectilinear motion. 
 
 3. Continued circular motion. 
 
 4. Reciprocating circular motion. 
 
 These will be more clearly understood by examples of each 
 kind. 
 
208 THE ELEMENTS OF MECHANICS. CHAP. XVIII 
 
 Continued rectilinear motion is observed in the flowing 
 of a river, in a fall of water, in the blowing of the wind, in 
 the motion of an animal upon a straight road, in the perpen- 
 dicular fall of a heavy body, in the motion of a body down 
 an inclined plane. 
 
 Reciprocating rectilinear motion is seen in the piston of a 
 common syringe, in the rod of a common pump, in the ham- 
 mer of a pavier, the piston of a steam-engine, the stampers 
 of a fulling-mill. 
 
 Continued circular motion is exhibited in all kinds of 
 wheel-work, and is so common, that to particularize it is 
 needless. 
 
 Reciprocating circular motion is seen in the pendulum of a 
 clock, and in the balance-wheel of a watch. 
 
 We shall now explain some of the contrivances by which 
 a power having one of these motions may be made to com- 
 municate either the same species of motion changed in its 
 velocity or direction, or any of the other three kinds of mo- 
 tion. 
 
 (314.) By a continued rectilinear motion another continu- 
 ed rectilinear motion in a different direction may be produced, 
 by one or more fixed pulleys. A cord passed over these, one 
 end of it being moved by the power, will transmit the same 
 motion unchanged to the other end. If the directions of the 
 two motions cross each other, one fixed^pulley will be suffi- 
 cient ; see jig. 113., where the hand takes the direction of 
 the one motion, and the weight that of the other. In this case, 
 the pulley must be placed in the angle at which the directions 
 of the two motions cross each other. If this angle be distant 
 from the places at which the objects in motion are situate, 
 an inconvenient length of rope may be necessary. In this 
 case, the same may be effected by the use of two pulleys, as 
 \njig. 158. 
 
 If the directions of the two motions be parallel, two pul- 
 leys must be used, as in Jig. 158., where P' A' is one motion, 
 and B W the other. In these cases, the axles of the two 
 wheels are parallel. 
 
 It may so happen that the directions of the two motions 
 neither cross each other nor are parallel. This would hap- 
 pen, for example, if the direction of one were upon the paper 
 in the line P A, while the other were perpendicular to the 
 paper from the point O. In this case, two pulleys should be 
 used, the axle of one O' being perpendicular to the paper, 
 
CHAP. XVIII. MODIFICATION OF MOTION. 209 
 
 while the axle of the other O should be on the paper. This 
 will be evident by a little reflection. 
 
 In general, the axle of each pulley must be perpendicular 
 to the two directions in which the rope passes from its groove ; 
 and by due attention to this condition it will be perceived, 
 that a continued rectilinear motion may be transferred from 
 any one direction to any other direction, by means of a cord 
 and two pulleys, without changing its velocity. 
 
 If it be necessary to change the velocity, any of the sys- 
 tems of pulleys described in Chapter XV. may be used in ad- 
 dition to the fixed pulleys. 
 
 By the wheel and axle any one continued rectilinear motion 
 may, be made to produce another in any other direction, and 
 with any other velocity. It has been already explained (250.) 
 that the proportion of the velocity of the power to that of the 
 weight is as the diameter of the wheel to the diameter of the 
 axle. The thickness of the axle being therefore regulated in 
 relation to the size of the wheel, so that their diameters shall 
 have that proportion which subsists between the proposed ve- 
 locities, one condition of the problem will be fulfilled. The 
 rope coiled upon the axle may be carried, by means of one or 
 more fixed pulleys, into the direction of one of the proposed 
 motions, while that which surrounds the wheel is carried into 
 the direction of the other by similar means. 
 
 (315.) By the wheel and axle a continued rectilinear mo- 
 tion may be made to produce a continued rotatory motion, or 
 vice versa. If the power be applied by a rope coiled upon 
 the wheel, the continued motion of the power in a straight 
 line will cause the machine to have a rotatory motion. Again, 
 if the weight be applied by a rope coiled upon the axle, a 
 power having a rotatory motion applied to the wheel will 
 cause the continued ascent of the weight in a straight line. 
 
 Continued rectilinear and rotatory motions may be made to 
 produce each other, by causing a toothed wheel to work in a 
 straight bar, called a rack, carrying teeth upon its edge. 
 Such an apparatus is represented in Jig. 159. 
 
 In some cases, the teeth of the wheel-work in the links of a 
 chain. The wheel is then called a rag-wheel, Jig. 160. 
 
 Straps, bands, or ropes, may communicate rotation to a 
 wheel, by their friction in a groove upon its edge. 
 
 A continued rectilinear motion is produced by a continued 
 circular motion in the case of a screw. The lever which 
 turns the screw has a continued circular motion, while the 
 18 * 
 
 . f. 
 
210 TIIE ELEMENTS OF MECHANICS. CHAP. XVIII. 
 
 screw itself advances with a continued rectilinear mo- 
 tion. 
 
 The continued rectilinear motion of a stream of water act- 
 ing upon a wheel produces continued circular motion in the 
 wheel, Jig. 93, 94, 95. In like manner the continued rectilin- 
 ear motion of the wind produces a continued circular mo- 
 tion in the arms of a windmill. 
 
 Cranes for raising and lowering heavy weights convert a 
 circular motion of the power into a continued rectilinear mo- 
 tion of the weight. 
 
 (310.) Continued circular motion may produce reciprocat- 
 ing rectilinear motion, by a great variety of ingenious con- 
 trivances. 
 
 Reciprocating rectilinear motion is used when heavy stamp- 
 ers are to be raised to a certain height, and allowed to fal! 
 upon some object placed beneath them. This may be accom- 
 plished by a wheel bearing on its edge curved teeth, called 
 wipers. The stamper is furnished with a projecting arm or 
 peg, beneath which the wipers are successively brought by 
 the revolution of the wheel. As the wheel revolves, the wiper 
 raises the stamper, until its extremity passes, the extremity of 
 the projecting arm of the stamper, when the latter immediate- 
 ly falls by its own weight. It is then taken up by the next 
 wiper, and so the process is continued. 
 
 A similar effect is produced if the wheel be partially fur- 
 nished with teeth, and the stamper carry a rack in which 
 these teeth work. Such an apparatus is represented in Jig. 
 161. 
 
 It is sometimes necessary that the reciprocating rectilinear 
 motion shall be performed at a certain varying rate in both 
 directions. This may be accomplished by the machine rep- 
 resented in Jig. 16*2. A wheel upon the axle C turns uniform- 
 ly in the direction A B D E. A rod m n moves in guides, 
 which only permit it to ascend and descend perpendicularly. 
 Its extremity m rests upon a path or groove raised from the 
 face of the wheel, and shaped into such a curve that, as the 
 wheel revolves, the rod mn shall be moved alternately in op- 
 posite directions through the guides, with the required veloci- 
 ty. The manner in which the velocity varies will depend on 
 the form given to the groove or channel raised upon the face 
 of the wheel, and this may be shaped so as to give any varia- 
 tion to the motion of the rod m n which may be required for 
 the purpose to which it is to be applied. 
 
CHAP. XVIII. MODIFICATION OF MOTION. 211 
 
 The rose-engine in the turning lathe is constructed on this 
 principle. It is also used in spinning machinery. 
 
 It is often necessary that the rod to which reciprocating 
 motion is communicated, shall be urged by the same force 
 in both directions. A wheel partially furnished with teeth, 
 acting on two racks placed on different sides of it, and both 
 connected with the bar or rod to which the reciprocating mo- 
 tion 1 is to be communicated, will accomplish this. Such an 
 apparatus is represented in jig. 163., and needs no further ex- 
 planation. 
 
 Another contrivance for the same purpose is shown in Jig. 
 164., where A is a wheel turned by a winch H, and connect- 
 ed with a rod or beam moving in guides by the joint a b. 
 As the wheel A is turned by the winch II, the beam is moved 
 between the guides alternately in opposite directions, the ex- 
 tent of its range being governed by the length of the diame- 
 ter of the wheel. Such an apparatus is used for grinding 
 and polishing plane surfaces, and also occurs in silk ma- 
 chinery. 
 
 An apparatus applied by M. Zureda in a machine for prick- 
 ing holes in leather is represented \njig. 165. The wheel A 
 B has its circumference formed into teeth, the shape of which 
 may be varied according to the circumstances under which it 
 is to be applied. One extremity of the rod a b rests upon the 
 teeth of the wheel, upon which it is pressed by a spring at the 
 other extremity. When the wheel revolves, it communicates 
 to this rod a reciprocating rectilinear motion. 
 
 Leupold has applied this mechanism to move the pistons of 
 pumps.* Upon the vertical axis of a horizontal hydraulic 
 wheel is fixed another horizontal wheel, which is furnished 
 with seven teeth, in the manner of a crown-wheel. (263.) 
 These teeth are shaped like inclined planes, the intervals be- 
 tween them being equal to the length of the planes. Pro- 
 jecting arms attached to the piston-rods rest upon the crown 
 of this wheel ; and, as it revolves, the inclined surfaces of the 
 teeth, being forced under the arm, raise the rod upon the prin- 
 ciple of the wedge. To diminish the obstruction arising from 
 friction, the projecting arms of the piston-rods are provided 
 with rollers, which run upon the teeth of the wheel. In one 
 revolution of the wheel each piston makes as many ascents 
 and descents as there are teeth. 
 
 * Theatrum Machinarum, torn. ii. pi. 36. fig. 
 
212 THE ELEMENTS OF MECHANICS. CHAP. XVIII. 
 
 (317.) Wheel- work furnishes numerous examples of con- 
 tinued circular motion round one axis, producing continued 
 circular motion round another. If the axles be in parallel 
 directions, and not too distant, rotation may be transmitted 
 from one to the other by two spur-wheels (263.); and the rela- 
 tive velocities may be determined by giving a corresponding 
 proportion to the diameter of the wheels. 
 
 If a rotatory motion is to be communicated from one axis 
 to another parallel to it, and at any considerable distance, 
 it cannot in practice be accomplished by wheels alone, for 
 their diameters would be too large. In this case, a strap or 
 chain is carried round the circumferences of both wheels. If 
 they are intended to turn in the same direction, -the strap is 
 arranged as in Jig, 100. ; but if in contrary directions, it is 
 .crossed as in Jig. 101. In this case, as with toothed wheels, 
 the relative velocities are determined by the proportion of the 
 diameters of the wheels. 
 
 If the axles be distant and not parallel, the cord, by which 
 the motion is transmitted, must be passed over grooved 
 wheels, or fixed pulleys, properly placed between the two 
 axles. 
 
 It may happen that the strain upon the wheel, to which the 
 motion is to be transmitted, is too great to allow of a strap or 
 cord being used. In this case, a shaft extending from the one 
 axis to another, and carrying two bevelled wheels (263.), will 
 accomplish the object. One of these bevelled wheels is 
 placed upon the shaft near to, and in connection with, the 
 wheel from which the motion is to be taken, and the other at 
 a part of it near to, and in connection with, that wheel to which 
 the motion is to be conveyed, Jig. 166. 
 
 The methods of transmitting rotation from one axis to 
 another perpendicular to it, by crown and by bevelled wheels, 
 have been explained in (263.) 
 
 The endless screw (299.) is a machine by which a rotatory 
 motion round one axis may communicate a rotatory motion 
 round another perpendicular to it. The power revolves 
 round an axis coinciding with the length of the screw, and 
 the axis of the wheel driven by the screw is at right angles 
 to this. 
 
 The axis to which rotation is to be given, or from which it 
 is to be taken, is sometimes variable in its position. In such 
 cases, an ingenious contrivance, called a universal joint, in- 
 vented by the celebrated Dr. Hooke, may be used. The two 
 
C1IAF. XVIII. UNIVERSAL JOINT. 213 
 
 shafts or axles A ^,fg. 167., between which the motion is to 
 be communicated, terminate in semicircles, the diameters of 
 which, C D and E F, are fixed in the form of a cross, their 
 extremities moving freely in bushes placed in the extremities 
 of the semicircles. Thus, while the central cross remains 
 unmoved, the shaft A and its semicircular end may revolve 
 round C D as an axis ; and the shaft B and its semicircular 
 end may revolve round E F as an axis. If the shaft A be 
 made to revolve without changing its direction, the points 
 C D will move in a circle whose centre is at the middle of the 
 cross. The motion thus given to the cross will cause the 
 points E F to move in another circle round the same centre, 
 and hence the shaft B will be made to revolve. 
 
 This instrument will not transmit the motion if the angle 
 under the directions of the shafts be less than 140. In this 
 case a double joint, as represented in Jig. 168., will answer 
 the purpose. This consists of four semicircles united by two 
 crosses, and its principle and operation are the same as in the 
 last case. 
 
 Universal joints are of great use in adjusting the position 
 of large telescopes, where, while the observer continues to look 
 through the tube, it is necessary to turn endless screws or 
 wheels, whose axes are not in an accessible position. 
 
 The cross is not indispensably necessary in the universal 
 joint. A hoop, with four pins projecting from it at four points 
 equally distant from each other, or dividing the circle of the 
 hoop into four equal arches, will answer the purpose. These 
 pins play in the bushes of the semicircles in the same manner 
 as those of the cross. 
 
 The universal joint is much used in cotton-mills, where 
 shafts are carried to a considerable distance from the prime 
 mover, and great advantage is gained by dividing them into 
 convenient lengths, connected by a joint of this kind. 
 
 (318.) In the practical application of machinery, it is often 
 necessary to connect a part having a continued circular mo- 
 tion with another which has a reciprocating or alternate 
 motion, so that either may move the other. There are many 
 contrivances by which this may be effected. 
 
 One of the most remarkable examples of it is presented 
 in the scapements of watches and clocks. In this case, 
 however, it can scarcely be said with strict propriety that it 
 is the rotation of the scapement-wheel (266.) which commu- 
 nicates the vibration to the balance-wheel or r>endulurrn. 
 
214 THE ELEMENTS Of MECHANICS. CHAP. XVIII. 
 
 That vibration is produced in the one case by the peculiar 
 nature of the spiral spring fixed upon the axis of the balance- 
 wheel, and, in the other case, by the gravity of the pendulum. 
 The force of the scapement*wheel only maintains the vibra- 
 tion, and prevents its decay by friction and atmospheric 
 resistance, Nevertheless, between the two parts thus moving, 
 there exists a mechanical connection, which is generally 
 brought within the class of contrivances now under consid- 
 eration. 
 
 A beam vibrating on an axis, and driven by the piston of a 
 steam-engine, or any other power, may communicate rotatory 
 motion to an axis, by a connector and a crank. This appara- 
 tus has been already described in (311.) Every steam-engine 
 which works by a beam affords an example of this. The 
 working beam is generally placed over the engine, the piston 
 rod being attached to one end of it, while the connecting 
 rod unites the other end with the crank. In boat-engines, 
 however, this position would be inconvenient, requiring more 
 room than could easily be spared. The piston rod, in these 
 cases, is, therefore, connected with the end of the beam by 
 long rods, and the beam is placed beside and below the 
 engine. Tne use of a fly-wheel here would also be objection- 
 able. The effect of the dead points explained in (311.) is 
 avoided without the aid of a fly, by placing two cranks upon 
 the revolving axle, and working them by two pistons. The 
 cranks are so placed that when either is at its dead point, 
 the other is in its most favorable position. 
 
 A wheel A, Jig. 169., armed with wipers, acting upon a 
 sledge-hammer B, fixed upon a centre or axle C, will, by a 
 continued rotatory motion, give the hammer the reciprocating 
 motion necessary for the purposes to which it is applied. 
 The manner in which this acts must be evident on inspecting 
 the figure. 
 
 The treddle of the lathe furnishes an obvious example of 
 a vibrating circular motion producing a continued circular 
 one. The treddle acts upon a crank, which gives motion to 
 the principal wheel, in the same manner as already described 
 in reference to the working beam and crank in the steam- 
 engine. 
 
 By the following ingenious mechanism, an alternate or 
 vibrating force may be made to communicate a circular mo- 
 tion continually in the same direction. Let A B,fig- 170., 
 be an axis receiving an alternate motion from some force 
 
 
CHAP. XVIII. MODIFICATION OP MOTION. 215 
 
 applied to it, such as a swinging weight. Two ratchet 
 wheels (253.) m and n are fixed on this axle, their teeth 
 being inclined in opposite directions. Two toothed wheels C 
 and D are likewise placed upon it, but so arranged that they 
 turn upon the axle with a little friction. These wheels car- 
 ry two catches jp, q, which fall into the teeth of the ratchet 
 wheels m, n, but fall on opposite sides, conformably to the in- 
 clination of the teeth already mentioned. The effect of these 
 catches is, that if the axis be made to revolve in one direction 
 one of the two toothed wheels is always compelled (by the 
 catch against which the motion is directed) to revolve with it, 
 while the other is permitted to remain stationary in obedience 
 to any force sufficiently great to overcome its friction with 
 the axle on which it is placed. The wheels C and D are 
 both engaged by bevelled teeth (263.) with the wheel E. 
 
 According to this arrangement, in whichever direction the 
 axis A B is made to revolve, the wheel E will continually 
 turn in the same direction, and, therefore, if the axle A B 
 be made to turn alternately in the one direction and the 
 other, the wheel E will not change the direction of its motion. 
 Let us suppose the axle A B is turned against the catch p, 
 The wheel C will then be made to turn with the axle. This 
 will drive the wheel E in the same direction. The teeth on 
 the opposite side of the wheel E being engaged with those 
 of the wheel D, the latter will be turned upon the axle, the 
 friction, which alone resists its motion in that direction, being 
 overcome. Let the motion of the axle A B be now reversed. 
 Since the teeth of the ratchet wheel n are moved against the 
 catch q, the wheel D will be compelled to revolve with 
 the axle. The wheel E will be driven in the same direction 
 as before, and the wheel C will be moved on the axle A B, 
 and in a contrary direction to the motion of the axle, the 
 friction being overcome by the force of the wheel E, Thus, 
 while the axle A B is turned alternately in the one direction 
 and the other, the wheel E is constantly moved in the same 
 direction. 
 
 It is evident that the direction in which the wheel E moves 
 may be reversed by changing the position of the ratchet 
 wheels and catches. 
 
 (319.) It is often necessary to communicate an alternate 
 circular motion, like that of a pendulum, by means of an 
 alternate motion in a straight line. A remarkable instance 
 of this occurs in the steam-engine, The moving force in 
 
216 THE ELEMENTS OF MECHANICS. CHAP. XVIII. 
 
 this machine is the pressure of steam, which impels a piston 
 from end to end alternately in a cylinder. The force of this 
 piston is communicated to the working beam by a strong rod, 
 which passes through a collar in one end of the piston. 
 Since it is necessary that the steam included in the cylinder 
 should not escape between the piston rod and the collar 
 through which it moves, and yet that it should move as freely, 
 and be subject to as little resistance, as possible, the rod is 
 turned so as to be truly cylindrical, and is well polished. 
 It is evident that, under these circumstances, it must not be 
 subject to any lateral or cross strain, which would bend it 
 towards one side or the other of the cylinder. But the end 
 of the beam to which it communicates motion, if connected 
 immediately with the rod by a joint, would draw it alternately 
 to the one side and the other, since it moves in the arc of a 
 circle, the centre of which is at the centre of the beam. It 
 is necessary, therefore, to contrive some method of connecting 
 the rod and the end of the beam, so that while the one shall 
 ascend and descend in a straight line, the other may move 
 in the circular arc. 
 
 The method which first suggests itself to accomplish this 
 is, to construct an arch-head upon the end of the beam, as in 
 Jig. 171. Let C be the centre on which the beam works, 
 and let B D be an arch attached to the end of the beam, 
 being a part of a circle having C for its centre. To the 
 highest point B of the arch a chain is attached, which is 
 carried upon the face of the arch B A, and the other end of 
 which is attached to the piston rod. Under these circum- 
 stances, it is evident that when the force of the steam impels 
 the piston downwards, the chain P A B will draw the end 
 of the beam down, and will, therefore, elevate the other end. 
 
 When the steam-engine is used for certain purposes, such 
 as pumping, this arrangement is sufficient. The piston in 
 that case is not forced upwards by the pressure of steam. 
 During its ascent it is not subject to the action of any force 
 of steam, and the other end of the beam falls by the weight 
 of the pump-rods drawing the piston, at the opposite end A, 
 to the top of the cylinder. Thus the machine is in fact pas- 
 sive during the ascent of the piston, and exerts its power 
 only during the descent. 
 
 If the machine, however, be applied to purposes in which 
 a constant action of the moving force is necessary, as is al- 
 ways the case in manufactures, the force of the piston must 
 
OHAP. XVIII. ALTERNATE MOTION OF A PISTON. 217 
 
 drive the beam in its ascent as well as in its descent. The 
 arrangement just described cannot effect this ; for although 
 a chain is capable of transmitting any force, by which its 
 extremities are drawn in opposite directions, yet it is, from 
 its flexibility, incapable of communicating a force which 
 drives one extremity of it towards the other. In the one 
 case, the piston first pulls down the beam, and then the beam 
 pulls up the piston. The chain, because it is inextensible, is 
 perfectly capable of both these actions ; and, being flexible, 
 it applies itself to the arch-head of the beam, so as to main- 
 tain the direction of its force upon the piston continually in 
 the same straight line. But when the piston acts upon the 
 beam in both ways, in pulling it down and pushing it up, the 
 chain becomes inefficient, being from its flexibility incapable 
 of the latter action. 
 
 The problem might be solved by extending the length of 
 the piston rod, so that its extremity shall be above the beam, 
 and using two chains ; one connecting the highest point of 
 the rod with the lowest point of the arch-head, and the other 
 connecting the highest point of the arch-head with a point 
 on the rod below the point which meets the arch-head when 
 the piston is at the top of the cylinder,^-. 172. 
 
 The connection required may also be made by arming the 
 arch-head with teeth, Jig. 173., and causing the piston rod 
 to terminate in a rack. In cases where, as in the steam-en- 
 gine, smoothness of motion is essential, this method is objec- 
 tionable ; and under any circumstances, such an apparatus is 
 liable to rapid wear. 
 
 The method contrived by Watt, for connecting the motion 
 of the piston with that of the beam, is one of the most in- 
 genious and elegant solutions ever proposed for a mechanical 
 problem. He conceived the motion of two straight rods 
 A B, C D,^g\ 174., moving on centres or pivots A and C, 
 so that the extremities B and D would move in the arcs of 
 circles, having their centres at A and C. The extremities 
 B and D of these rods he conceived to be connected with a 
 third rod B D united with them by pivots on which it could 
 turn freely. To the system of rods thus connected let an 
 alternate motion on the centres A and C be communicated ; 
 the points B and D will move upwards and downwards in 
 the arcs expressed by the dotted lines, but the middle point 
 P of the connecting rod B D will move upwards and down- 
 wards without any sensible deviation from a straight line. 
 19 
 
THE ELEMENTS OF MECHANICS. CHAP. XVIII. 
 
 To prove this demonstratively would require some abstruse 
 mathematical investigation. It may, however, be rendered 
 in some degree apparent by reasoning of a looser and more 
 popular nature. As the point B is raised to E, it is also drawn 
 aside towards the right. At the same time, the other extremity 
 D of the rod B D is raised to E 7 , and is drawn aside towards 
 the left. The ends of the rod B D being thus at the same 
 time drawn equally towards opposite sides, its middle point P 
 will suffer no lateral derangement, and will move directly 
 upwards. On tho other hand, if B be moved downwards to 
 F, it will be drawn laterally to the right, while D, being 
 moved to F 7 , will be drawn, to the left. Hence, as before, 
 the middle point P sustains no lateral derangement, but 
 merely descends. Thus as the extremities B and D move 
 upwards and downwards in circles, the middle point P moves 
 upwards and downwards in a straight line.* 
 
 The application of this geometrical principle in the steam- 
 engine evinces much ingenuity. The same arm of the beam 
 usually works two pistons, that of the cylinder and that of 
 the air-pump. The apparatus is represented on the arm of 
 the beam in Jig. 175. The beam moves alternately upwards 
 and downwards on its axis A. Every point of it, therefore, 
 describes a part of a circle of which A is the centre. Let 
 B be the point which divides the arm A G into two equal 
 parts A B and B G ; and let C D be a straight rod, equal in 
 length to G B, and fixed on a centre or pivot C on which it 
 is at liberty to play. The end D of this rod is connected by 
 a straight bar with the point B, by pivots on which the rod 
 B D turns freely. If the beam be now supposed to rise and 
 fall alternately, the points B and D will move upwards and 
 downwards in circular arcs, and, as already explained with 
 respect to the points B D, Jig. 174., the middle point P of 
 the connecting rod B D will move upwards and downwards 
 without lateral deflection. To this point one of the piston 
 rods which are to be worked is attached. 
 
 To comprehend the method of working the other piston, 
 conceive a rod G P 7 , equal in length to B D, to be attached 
 to the end G of the beam by a pivot on which it moves freely ; 
 
 * In a strictly mathematical sense, the path of the point P is a curve, and 
 not a straight line ; but in the play given to it in its application to the steam- 
 engine, it moves through a part only of its entire locus, and this part extend- 
 ing equally on each side of a point of inflection, the radius of curvature is 
 infinite, so that in practice the deviation from a straight line, when proper pro 
 portions are observed in the rods, is imperceptible 
 
CHAP. XIX. FRICTION. 219 
 
 arid let its extremity P' be connected with D by another rod 
 P' D, equal in length to G B, and playing on points at P' and 
 D. The piston rod of the cylinder is attached to the point 
 P 7 , and this point has a motion precisely similar to that of P, 
 without any lateral derangement, but with a range in the per- 
 pendicular direction twice as great. This will be apparent 
 by conceiving a straight line drawn from the centre A of the 
 beam to P', which will also pass through P. Since G P' is 
 always parallel to B P, it is evident that the triangle P' G A 
 is always similar to P B A, and has its sides and angles simi- 
 larly placed, but those sides are each twice the magnitude of 
 the corresponding sides of the other triangle. Hence the 
 point P' must be subject to the same changes of position as 
 the point P, with this difference only, that in the same time 
 it moves over a spaee of twice the magnitude. In fact, the 
 line traced by P' is the same as that traced by P, but on a 
 scale twice as large. This contrivance is usually called the 
 parallel motion, but the same name is generally applied to all 
 contrivances by which a circular motion is made to produce 
 - ^ctilinear one. 
 
 CHAPTER XIX. 
 
 OF FRICTION AND THE RIGIDITY OF CORDAGE. 
 
 (320.) WITH a view to the simplification of the elementary 
 theory of machines, the consideration of several mechanical 
 effects of great practical importance has been postponed, and 
 the attention of the student has been directed exclusively to 
 the way in which the moving power is modified in being 
 transmitted to the resistance independently of such effects. 
 A machine has been regarded as an instrument by which a 
 moving principle, inapplicable in its existing state to the pur- 
 pose for which it is required, may be changed either in its 
 velocity or direction, or in some other character, so as to be 
 adapted to that purpose. But in accomplishing this, the sev- 
 eral parts of the machine have been considered as possessing 
 in a perfect degree qualities which they enjoy only in an im- 
 perfect degree ; and accordingly the conclusions to which by 
 such reasoning we are conducted are infected with errors, 
 
220 THE ELEMENTS OF MECHANICS. CHAP. XIX 
 
 the amount of which will depend on the degree in which the 
 machinery falls short of perfection in those qualities which 
 theoretically are imputed to it. 
 
 Of the several parts of a machine, some are designed to 
 move, while others are fixed ; and of those which move, some 
 have motions differing in quantity and direction from those 
 of others. The several parts, whether fixed or movable, are 
 subject to various strains and pressures, which they are in- 
 tended to resist. These forces not only vary according to 
 the load which the machine has to overcome, but also accord- 
 ing to the peculiar form and structure of the machine itself. 
 During the operation, the surfaces of the movable parts move 
 in immediate contact with the surfaces either of fixed parts 
 or of parts having other motions. If these surfaces were 
 endued with perfect smoothness or polish, and the several 
 parts subject to strains possessed perfect inflexibility and in- 
 finite strength, then the effects of machinery might be practi- 
 cally investigated by the principles already explained. But 
 the materials of which every machine is formed are endued 
 with limited strength, and therefore the load which is placed 
 upon it must be restricted accordingly, else it will be liable 
 to be distorted by the flexure, or even to be destroyed by the 
 fracture of those parts which are submitted to an undue 
 strain. The surfaces of the movable parts, and those surfaces 
 with which they move in contact, cannot in practice be ren- 
 dered so smooth but that such roughness and inequality will 
 remain as sensibly to impede the motion. To overcome such 
 an impediment requires no inconsiderable part of the moving 
 power. This part is, therefore, intercepted before its arrival 
 at the working point, and the resistance to be finally overcome 
 is deprived of it. The property thus depending on the im- 
 perfect smoothness of surfaces, and impeding the motion of 
 bodies whose surfaces are in immediate contact, is called 
 friction. Before we can form a just estimate of the effects 
 of machinery, it is* necessary to determine the force lost by 
 this impediment, and the laws which, under different circum- 
 stances, regulate that loss. 
 
 When cordage is engaged in the formation of any part of 
 a machine, it has hitherto been considered as possessing per- 
 fect flexibility. This is not the case in practice ; and the 
 want of perfect flexibility, which is called rigidity, renders a 
 certain quantity of force necessary to bend a cord or rope 
 over the surface of an axle or the groove of a wheel. During 
 
CHAP. XIX. FRICTION. 221 
 
 the motion of the tope, a different part of it must thus be con- 
 tinually bent, and the force which is expended in producing 
 the necessary flexure must be derived from the moving power, 
 and is thus intercepted on its way to the working point. In 
 calculating the effects of cordage, due regard must be had to 
 this waste of power ; and therefore it is necessary to inquire 
 into the laws which govern the flexure of imperfectly flexible 
 ropes, and the way in which these affect the machines in 
 which ropes are commonly used. 
 
 To complete, therefore, the elementary theory of machine- 
 ry, we propose in the present and following chapter to explain 
 the principal laws which determine the effects of friction, the 
 rigidity of cordage, and the strength of materials. 
 
 (321.) If a horizontal plane surface were perfectly smooth, 
 and free from the smallest inequalities, and a body having a 
 flat surface, also perfectly smooth, were placed upon it, any 
 force applied to the latter would put it in motion, and that 
 motion would continue undimjnished as long as the body 
 would remain upon the smooth horizontal surface. But if 
 this surface, instead of being every where perfectly even, had 
 in particular places small projecting eminences, a certain 
 quantity of force would be necessary to carry the moving body 
 over these, and a proportional diminution in its rate of motion 
 would ensue. Thus, if such eminences were of frequent 
 occurrence, each would deprive the body of apart of its speed, 
 so that between that and the next it would move with a less 
 velocity than it had between the same and the preceding one. 
 This decrease being continued by a sufficient number of such 
 eminences encountering the body in succession, the velocity 
 would at last be so much diminished, that the body would not 
 have sufficient force to carry it over the next eminence, and 
 its motion would thus altogether cease. 
 
 Now, instead of the eminences being at a considerable dis- 
 tance asunder, suppose them to be contiguous, and to be 
 spread in every direction over the horizontal plane, and also 
 suppose corresponding eminences to be upon the surface of the 
 moving body ; these projections incessantly encountering one 
 another will continually obstruct the motion of the body, and 
 will gradually diminish its velocity, until it be reduced to a 
 state of rest. 
 
 Such is the cause of friction. The amount of this resist- 
 ing force increases with the magnitude of these asperities, or 
 with the roughness of the surfaces ; but it does not solely de- 
 19* 
 
THE ELEMENTS OF MECHANICS. CHAP. XIX. 
 
 pend on this. The surfaces remaining the same, a little re- 
 flection on the method of illustration just adopted, will show 
 that the amount of friction ought also to depend upon the force 
 with which the surfaces moving one upon the other are press- 
 ed together. It is evident, that as the weight of the body 
 supposed to move upon the horizontal plane is increased, a pro- 
 portionally greater force will be necessary to carry it over the 
 obstacles which it encounters, and therefore it will the more 
 speedily be deprived of its velocity and reduced to a state of 
 rest. 
 
 (322.) Thus we might predict with probability, that which 
 accurate experimental inquiry proves to be true, that the re- 
 sistance from friction depends conjointly on the roughness of 
 the surfaces and the force of the pressure. When the sur- 
 faces are the same, a double pressure will produce a double 
 amount of friction, a treble pressure a treble amount of fric- 
 tion, and so on. 
 
 Experiment also, however, gives a result which, at least at 
 first view, might not have been anticipated from the mode of 
 illustration we have adopted. It is found that the resistance 
 arising from friction does not at all depend on the magnitude 
 of the surface of contact ; but provided the nature of the sur- 
 faces and the amount of pressure remain the same, this resist- 
 ance will be equal, whether the surfaces which move one upon 
 the other be great or small. Thus, if the moving body be a 
 flat block of wood, the face of which is equal to a square foot 
 in magnitude, and the edge of which does not exceed a square 
 inch, it will be subject to the same amount of friction, wheth- 
 er it move upon its broad face or upon its narrow edge. If 
 we consider the effect of the pressure in each case, we shall 
 be able to perceive why this must be the case. Let us sup- 
 pose the weight of the block to be 144 ounces. When it 
 rests upon its face, a pressure to this amount acts upon a sur- 
 face of 144 square inches, so that a pressure of one ounce 
 acts upon each square inch. The total resistance arising from 
 friction will, therefore, be 144 times that resistance which 
 would be produced by a surface of one square inch under a 
 pressure of one ounce. Now, suppose the block placed upon 
 its edge, there is then a pressure of 144 ounces upon a sur- 
 face equal to one square inch. But it has been already shown, 
 that when the surface is the same, the friction must increase 
 in proportion to the pressure. Hence we infer, that the fric- 
 tion produced in the present case is 144 times the friction 
 
CHAP. XIX. FRICTION. 223 
 
 which would be produced by a pressure of one ounce acting 
 on one square inch of surface, which is the same resistance 
 as that which the body was proved to be subject to when rest- 
 ing on its face. 
 
 These two laws, that friction is independent of the magni- 
 tude of the surface, and is proportional to the pressure, when 
 the quality of the surfaces is the same, are useful in practice, 
 and generally true. In very extreme cases they are, however, 
 in error. When the pressure is very intense, in proportion to 
 the surface, the friction is somewhat less than it would be by 
 these laws ; and when it is very small in proportion to the sur- 
 face, it is somewhat greater. 
 
 (323.) There are two methods of establishing by experi- 
 ment the laws of friction, which have been just explained. 
 
 First. The surfaces between which the friction is to be 
 determined being rendered perfectly flat, let one be fixed in 
 the horizontal position on a table T T', Jig. 176. ; and let 
 the other be attached to the bottom of a box B C, adapted to 
 receive weights, so as to vary the pressure. Let a silken cord 
 S P, attached to the box, be carried parallel to the table over 
 a wheel at P, and let a dish D be suspended from it. If no 
 friction existed between the surfaces, the smallest weight ap- 
 pended to the cord would draw the box towards P with a con- 
 tinually increasing speed. But the friction which always ex- 
 ists interrupts this effect, and a small weight may act upon 
 the string without moving the box at all. Let weights be 
 put in the dish D, until a sufficient force is obtained to over- 
 come the friction without giving the box an accelerated motion. 
 Such a weight is equivalent to the amount of the friction. 
 
 The amount of the weight of the box being previously as- 
 certained, let this weight be now doubled by placing addition- 
 al weights in the box. The pressure will thus be doubled, 
 and it will be found that the weight of the dish D and its 
 load, which before was able to overcome the friction, is now 
 altogether inadequate to it, Let additional weights be placed 
 in the dish, until the friction be counteracted as before, and it 
 will be observed, that the whole weight necessary to produce 
 this effect is exactly twice the weight which produced it in 
 the former case. Thus it appears that a double amount of 
 pressure produces a double amount of friction ; and in a sim- 
 ilar way it may be proved, that any proposed increase or de- 
 crease of the pressure will be attended with a proportionate 
 variation in the amount of the friction. 
 
224 TUB ELEMENTS OF MECHANICS. CHAP. XIX 
 
 Second. Let one of the surfaces be attached to a flat plane 
 A B,Jig. 177., which can be placed at any inclination with an 
 horizontal plane B C, the other surface being, as before, at- 
 tached to the box adapted to receive weights. The box be- 
 ing placed upon the plane, let the latter be slightly elevated. 
 The tendency of the box to descend upon A B will bear the 
 same proportion to its entire weight as the perpendicular A E 
 bears to the length of the plane A B (2HG.). Thus if the 
 length A B be 30 inches, and the height A E be three inches, 
 that is, a twelfth part of the length, then the tendency of the 
 weight to move down the plane is equal to a twelfth part of 
 its whole amount. If the weight were twelve ounces, and 
 the surfaces perfectly smooth, a force of one ounce acting up 
 the plane would be necessary to prevent the descent of the 
 weight. 
 
 In this case also, the pressure on the plane will be repre- 
 sented by the length of the base B E (280.), thai is, it will 
 bear the same proportion to the whole weight as B E bears to 
 B A. The relative amounts of the weight, the tendency to 
 descend, and the pressure, will always be exhibited by the rel- 
 ative lengths of A B, A E, and B E. 
 
 This being premised, let the elevation of the plane A B be 
 gradually increased, until the tendency of the weight to de- 
 scend just overcomes the friction, but not so much as to allow 
 the box to descend with accelerated speed. The proportion 
 of the whole weight, which then acts down the plane, will be 
 found by measuring the height A E, and the pressure will be 
 determined by measuring the base B E. Now let the weight 
 in the box be increased, and it will be found that the same 
 elevation is necessary to overcome the friction ; nor will this 
 elevation suffer any change, however the pressure or the 
 magnitude of the surfaces which move in contact may be 
 varied. 
 
 Since, therefore, in all these cases, the height A E and the 
 base B E remain the same, it follows that the proportion be- 
 tween the friction and pressure is undisturbed. 
 
 (324.) The law that friction is proportional to the pressure, 
 has been questioned by the late professor Vince of Cambridge, 
 who deduced from a series of experiments, that although the 
 friction increases with the pressure, yet that it increases in a 
 somewhat less ratio ; and from this it would follow, that the 
 variation of the surface of contact must produce some effect 
 upon the amount of friction. The law as we have explained 
 

 CHAP. XIX, FRICTION. 225 
 
 it, however, is sufficiently near the truth for most practical 
 purposes. 
 
 (325.) There are several circumstances regarding the 
 quality of the surfaces, which produce important effects on 
 the quantity of friction, and which ought to be noticed 
 here. 
 
 This resistance is different in the surfaces of different sub- 
 stances. When the surfaces are those of wood newly planed, 
 it amounts to about half the pressure, but is different in dif- 
 ferent kinds of wood. The friction of metallic surfaces is 
 about one fourth of the pressure. 
 
 In general, the friction between the surfaces of bodies of 
 different kinds is less than between those of the same kind. 
 Thus, between wood and metal, the friction is about one fifth 
 of the pressure. 
 
 It is evident that the smoother the surfaces are, the less 
 will be the friction. On this account, the friction of surfaces, 
 when first V 'ought into contact, is often greater than after 
 their attrition has been continued for a certain time, because 
 that process has a tendency to remove and rub off those mi- 
 nute asperities and projections on which the friction depends. 
 But this has a limit, and after a certain quantity of attrition, 
 the friction ceases to decrease. Newly planed surfaces of 
 wood have at first a degree of friction which is equal to half 
 the entire pressure, but after they are worn by attrition, it is 
 reduced to a third. 
 
 If the surfaces in contact be placed with their grains in the 
 same direction, the friction will be greater than if the grains 
 cross each other. 
 
 Smearing the surfaces with unctuous matter, diminishes 
 the friction, probably by filling the cavities between the minute 
 projections which produce the friction. 
 
 When the surfaces are first placed in contact, the friction is 
 less than when they are suffered to rest so for some time ; 
 this is proved by observing the force which in each case is 
 necessary to move the one upon the other, that force being 
 less if applied at the first moment of contact than when the 
 contact has continued. This, however, has a limit. There 
 is a certain time, different in different substances, within 
 which this resistance attains its greatest amount. In surfaces 
 of wood, this takes place in about two minutes ; in metals, the 
 time is imperceptibly short ; and when a surface of wood is 
 placed upon a surface of metal, it continues to increase for 
 
226 THE ELEMENTS OF MECHANICS. CHAP. XIX. 
 
 several days. The limit is larger when the surfaces are great, 
 and belong to substances of different kinds. 
 
 The velocity with which the surfaces move upon one another 
 produces but little effect upon the friction. 
 
 (326.) There are several ways in which bodies may move 
 one upon the other, in which friction will produce different 
 effects. The principal of these are, first, the case where one 
 body slides over another; the second, where a body having a 
 round form rolls upon another ; and, thirdly, where an axis 
 revolves within a hollow cylinder, or the hollow cylinder re- 
 volves upon the axis. 
 
 With the same amount of pressure and a like quality of 
 surface, the quantity of friction is greatest in the first case 
 and least in the second. The friction in the second case also 
 depends on the diameter of the body which rolls, and is small 
 in proportion as that diameter is great. Thus a carriage with 
 large wheels is less impeded by the friction of the road than 
 one with small wheels. 
 
 In the third case, the leverage of the wheel aids the power 
 in overcoming the friction. "Let Jig. 178. represent a section 
 of the wheel and axle ; let C be the centre of the axle, and 
 let B E be the hollow cylinder in the nave of the wheel in 
 which the axle is inserted. If B be the part on which the 
 axle presses, and the wheel turn in the direction N D M, the 
 friction will act at B in the direction B F, arid with the lever- 
 age B C. The power acts against this at D in the direction 
 D A, and with the leverage D C. It is therefore evident, 
 that as D C is greater than B C, in the same proportion 
 does the power act with mechanical advantage on the fric- 
 tion. 
 
 (327.) Contrivances for diminishing the effects of friction 
 depend on the properties just explained, the motion of rolling 
 being as much as possible substituted for that of sliding; and 
 where the motion of rolling cannot be applied, that of a wheel 
 upon its axle is used. In some cases, both these motions are 
 combined. 
 
 If a heavy load be drawn upon a plane in the manner of a 
 sledge, the motion will be that of sliding, the species which 
 is attended with the greatest quantity of friction ; but if the 
 load be placed upon cylindrical rollers, the nature of the mo- 
 tion is changed, and becomes that in which there is the least 
 quantity of friction. Tims large blocks of stone, or heavy 
 beams of timber, which would require an enormous power to 
 
CHAP. XIX. FRICTION. 227 
 
 move them on a level road, are easily advanced when rollers 
 are put under them. 
 
 When very heavy weights are to be moved through small 
 spaces, this method is used with advantage ; but when loads 
 are to be transported to considerable distances, the process is 
 inconvenient and slow, owing to the necessity of continually 
 replacing the rollers in front of the load as they are left be- 
 hind by its progressive advancement. 
 
 The wheels of carriages may be regarded as rollers which 
 are continually carried forward with the load. In addition 
 to the friction of the rolling motion on the road, they have, it 
 is true, the friction of the axle in the nave ; but, on the other 
 hand, they are free from the friction of the rollers with the 
 under surface of the load, or the carriage in which the load 
 is transported. The advantage of wheel carriages in dimin- 
 ishing the effects of friction, is sometimes attributed to the 
 slowness with which the axle moves within the box, compar- 
 ed with the rate at which the wheel moves over the road ; but 
 this is erroneous. The quantity of friction does not in any 
 case vary considerably with the velocity of the motion, but 
 least of all does it in that particular kind of motion here con- 
 sidered. 
 
 In certain cases, where it is of great importance to remove 
 the effects of friction, a contrivance called friction-wheels, or 
 friction-rollers, is used. The axle of a friction-wheel, instead 
 of revolving within a hollow cylinder, which is fixed, rests 
 upon the edges of wheels which revolve with it ; the species 
 of motion thus becomes that in which the friction is of least 
 amount. 
 
 Let A B and D C, Jig. 179., be two wheels revolving on 
 pivots P Q, with as little friction as possible, and so placed 
 that the axle O of a third wheel E F may rest between their 
 edges. As the wheel E F revolves, the axle O, instead of 
 grinding its surface on the surface on which it presses, car- 
 ries that surface with it, causing the wheels A B, C D, to re- 
 volve. 
 
 In wheel carriages, the roughness of the road is more 
 easily overcome by large wheels than by small ones. The 
 cause of this arises partly from the large wheels not being so 
 liable to sink into holes as small ones, but more because, in 
 surmounting obstacles, the load is elevated less abruptly. This 
 will be easily understood by observing the curves in Jig. 180., 
 which represent the elevation of the axle in each case. 
 
228 THE ELEMENTS OF MECHANICS. CHAP. XIX. 
 
 (328.) If a carriage were capable of moving on a road 
 without friction, the most advantageous direction in which a 
 force could be applied to draw it would be parallel to the 
 road. When the motion is impeded by friction, it is better, 
 however, that the line of draught should be inclined to the 
 road, so that the drawing force may be expended partly in 
 lessening the pressure on the road, and partly in advancing 
 the load. 
 
 Let W, Jig. 181., be a load which is to be moved upon the 
 plane surface A B. If the drawing force be applied in the 
 direction C D, parallel to the plane A B, it will have to over- 
 come the friction produced by the pressure of the whole 
 weight of the load upon the plane; but if it be inclined up- 
 wards in the direction C E, it will be equivalent to two forces 
 expressed (74.) by C G and C F. The part C G has the 
 effect of lightening the pressure of the carriage upon the 
 road, and therefore of diminishing the friction in the same 
 proportion. The part C F draws the load along the plane. 
 Since C F is less than C E or C D, the whole moving force, 
 it is evident that a part of the force of draught is lost by this 
 obliquity ; but, on the other hand, a part of the opposing re- 
 sistance is also removed. If the latter exceed the former, an 
 advantage will be gained by the obliquity ; but if the former 
 exceed the latter, force will be lost. 
 
 By mathematical reasoning, founded on these considera- 
 tions, it is proved that the best angle of draught is exactly 
 that obliquity which should be given to the road in order to 
 enable the carriage to move of itself. This obliquity is 
 sometimes called the angle of repose, and is that angle which 
 determines the proportion of the friction to the pressure in 
 the second method explained in (323.) The more rough 
 the road is, the greater will this angle be ; and therefore it 
 follows, that on bad roads the obliquity of the traces to the 
 road should be greater than on good ones. On a smooth 
 Macadamized way, a very slight declivity would cause a car- 
 riage to roll by its own weight : hence, in this case, the 
 traces should be nearly parallel to the road. 
 
 In rail-roads, for like reasons, the line of draught should 
 be parallel to the road, or nearly so. 
 
 (329.) When ropes or cords form a part of machinery, the 
 effects of their imperfect flexibility are, in a certain degree, 
 counteracted by bending them over the grooves of wheels. 
 But although this so far diminishes these effects as to render 
 
CHAP. XX. STRENGTH OP MATERIALS. 229 
 
 rapes practically useful, yet still, in calculating the powers of 
 machinery, it is necessary to take into account some conse- 
 quences of the rigidity of cordage, which, even by these 
 means, are not removed. 
 
 To explain the way in which the stiffness of a rope modi- 
 fies the operation of a machine, we shall suppose it bent over 
 a wheel, and stretched by weights A B, Jig. 182., at its ex- 
 tremities. The weights A and B being equal, and acting at 
 C and D in opposite ways, balance the wheel. If the weight 
 A receive an addition, it will overcome the resistance of B, 
 and turn the wheel in the direction DEC. Now, for the 
 present, let us suppose that the rope is perfectly inflexible ; 
 the wheel and weights will be turned into the position repre- 
 sented in Jig. 183. The leverage by which A acts will be 
 diminished, and will become O F, having been before O C ; 
 and the leverage by which B acts will be increased to O G, 
 having been before O D. 
 
 But the rope, not being inflexible, will yield partially to the 
 effects of the weights A and B, and the parts A C and B D 
 will be bent into the forms represented in Jig. 184. The 
 form of the curvature which the rope on each side of the 
 wheel receives is still such that the descending weight A 
 works with a diminished leverage F O, while the ascending 
 weight resists it with an increased leverage G O. Thus so 
 much of the moving power is lost, by the stiffness of the 
 rope, as is necessary to compensate this disadvantageous 
 change in the power of the machine; 
 
 CHAPTER XX. 
 
 ON THE STRENGTH OF MATERIALS. 
 
 (330.) EXPERIMENTAL inquiries into the laws which regu 
 late the strength of solid bodies, or their power to resist 
 forces variously applied to tear or break them, are obstructed 
 by practical difficulties, the nature and extent of which are 
 so discouraging, that few have ventured to encounter them 
 at all, and still fewer the steadiness to persevere until any 
 result showing a general law has been obtained. These 
 difficulties arise, partly from the great forces which must be 
 applied, but more from the peculiar nature of the objects of 
 20 
 
230 THE ELEMENTS OF MECHANICS. CHAP. XX 
 
 those experiments. The end to which such an inquiry must 
 be directed is the developement of a general Irtw ; that is, 
 such a rule as would be rigidly observed if the materials, the 
 strength of which is the object of inquiry, were perfectly 
 uniform in their texture, and subject to no casual inequalities. 
 In proportion as these inequalities are frequent, experiments 
 must be multiplied, that a long average may embrace cases 
 varying in both extremes, so as to eliminate each other's 
 effects in the final result. 
 
 The materials of which structures and works of art are 
 composed are liable to so many and so considerable inequali- 
 ties of texture, that any rule which can be deduced, even by 
 the most extensive series of experiments, must be regarded 
 as a mean result, from which individual examples will be 
 found to vary in so great a degree, that more than usual cau- 
 tion must be observed in its practical application. The de- 
 tails- of this subject belong to engineering more properly 
 than to the elements of mechanics. Nevertheless, a general 
 view of the most important principles which have been es- 
 tablished respecting the strength of materials will not be 
 misplaced in this treatise. 
 
 A piece of solid matter may be submitted to the action of 
 a force tending to separate its parts in several ways ; the 
 principal of which are, 
 
 1. To a direct putt, as when a rope or wire is stretched 
 by a weight ; when a tie-beam resists the separation of the 
 sides of a structure, &,c. 
 
 2. To a direct pressure or thrust, as when a weight rests 
 upon a pillar. 
 
 3. To a transverse strain, as when weights on the ends 
 of a lever press it on the fulcrum. 
 
 (331.) If a solid be submitted to a force which draws it in 
 the direction of its length, having a tendency to pull its ends 
 in opposite directions, its strength or power to resist such a 
 force is proportional to the magnitude of its transverse section. 
 Thus, suppose a square rod of metal A B, Jig. 185., of the 
 breadth and thickness of one inch, be pulled by a force in 
 the direction A B, and that a certain force is found sufficient 
 to tear it ; a rod of the same metal of twice the breadth and 
 the same thickness will require double the force to break it ; 
 one of treble the breadth and the same thickness will require 
 treble the force to break it ; and so on. 
 
 The reason of this is evident. A rod of double or treble 
 
CHAP. XX. STRENGTH OF BEAMS. 231 
 
 the thickness, in this case, is equivalent to two or three equal 
 and similar rods which equally and separately resist the draw- 
 ing force, and therefore possess a degree of strength pro- 
 portionate to their number. 
 
 It will easily be perceived, that whatever be the section, 
 the same reasoning will be applicable, and the power of re- 
 sistance will, in general, be proportional to its magnitude or 
 area. 
 
 If the material were perfectly uniform throughout its di- 
 mensions, the resistance to a direct pull would not be affected 
 by the length of the rod. In practice, however, the increase 
 of length is found to lessen the strength. This is to be at- 
 tributed to the increased chance of inequality. 
 
 (332.) No satisfactory results have been obtained either 
 by theory or experiment respecting the laws by which solids 
 resist compression. The power of a perpendicular pillar to 
 support a weight placed upon it, evidently depends on its 
 thickness, or the magnitude of its base, and on its height. 
 It is certain that when the height is the same, the strength 
 increases with every increase of the base ; but it seems doubt- 
 ful whether the strength be exactly proportional to the base. 
 That is, if two columns of the same material have equal 
 heights, and the base of one be double the base of the other, 
 the strength of one will be greater, but it is not certain 
 whether it will exactly double that of the other. According 
 to the theory of Euler, which is, in a certain degree, verified 
 by the experiments of Musschen brock, the strength will be 
 increased in a greater proportion than the base, so that if the 
 base be doubled, the strength will be more than doubled. 
 
 When the base is the same, the strength is diminished by 
 increasing the height, and this decrease of strength is propor- 
 tionally greater than the increase of height. According to 
 Euler's theory, the decrease of strength is proportional to the 
 square of the height; that is, when the height is increased 
 in a two-fold proportion, the strength is diminished in a four- 
 fold proportion. 
 
 (333.) The strain to which solids forming the parts of 
 structures of every kind are most commonly exposed, is the 
 lateral or transverse strain, or that which acts at right angles 
 to their lengths. If any strain act obliquely to the direction 
 of their length, it may be resolved into two forces (76.), one 
 in the direction of the length, and the other at right angles 
 to the length. That part which acts in the direction of the 
 
232 THE ELEMENTS OF MECHANICS. CHAP. XX. 
 
 length will produce either compression or a direct pull, and 
 its effect must be investigated accordingly. 
 
 Although the results of theory, as well as those of experi- 
 mental investigations, present great discordances respecting 
 the transverse strength of solids, yet there are some particu- 
 lars, in which they, for the most part, agree ; to these it is our 
 object here to confine our observations, declining all details 
 relating to disputed points. 
 
 Let A B C D, Jig. 186., be a beam, supported at its ends 
 A and B. Its strength to support a weight at E, pressing 
 downwards at right angles to its length, is evidently propor- 
 tional to its breadth, the other things being the same. For 
 a beam of double or treble breadth, and of the same thick- 
 ness, is equivalent to two or three equal and similar beams 
 placed side by side. Since each of these would possess the 
 same strength, the whole taken together would possess double 
 or treble the strength of any one of them. 
 
 When the breadth and length are the same, the strength 
 obviously increases with the depth, but not in the same pro- 
 portion. The increase of strength is found to be much greater 
 in proportion than the increase of depth. By the theory of 
 Galileo, a double or treble thickness ought to increase the 
 strength in a four-fold or nine-fold proportion, and experi- 
 ments, in most cases, do not materially vary from this rule. 
 
 If, while the breadth and depth remain the same, the length 
 of the beam, or rather the distance between the points of 
 support, vary, the strength will vary accordingly, decreasing 
 in the same proportion as the length increases. 
 
 From these observations it appears, that the transverse 
 strength of a beam depends more on its thickness than its 
 breadth. Hence we find that a broad thin board is much 
 stronger when its edge is presented upwards. On this prin- 
 ciple the joists or rafters of floors and roofs are constructed. 
 
 If two beams be in all respects similar, their strengths will 
 be in the proportion of the squares of their lengths. Let the 
 length, breadth and depth of the one be respectively double 
 the length, breadth and depth of the other. By the double 
 breadth the beam doubles its strength, but by doubling the 
 length half this strength is lost. Thus the increase of length 
 and breadth counteract each other's effects, and, as far as they 
 are concerned, the strength of the beam is not changed. 
 But by doubling the thickness, the strength is increased in a 
 four-fold proportion, that is, as the square of the length. In 
 
CHAP. XX. STRENGTH OF A STRUCTURE. 233 
 
 the same manner it may be shown, that when all the dimen- 
 sions are trebled, the strength is increased in a nine-fold 
 proportion, and so on. 
 
 (334.) In all structures the materials have to support their 
 own weight, and therefore their available strength is to be 
 estimated by the excess of their absolute strength above that 
 degree of strength which is just sufficient to support their 
 own weight. This consideration leads to some conclusions, 
 of which numerous and striking illustrations are presented 
 in the works of nature and art. 
 
 We have seen that the absolute strength with which a lat- 
 eral strain is resisted is in the proportion of the square of the 
 linear dimensions of similar parts of a structure, and there- 
 fore the amount of this strength increases rapidly with every 
 increase of the dimensions of a body. But at the same time 
 t!ie wei^'it of the body increases in a still more rapid propor- 
 tion. Thus, if the several dimensions be doubled, the 
 strength will be increased in a four-fold, but the weight in an 
 eight-fold proportion. If the dimensions be trebled, the 
 strength will be multiplied nine times, but the weight twenty- 
 seven times. Again, if the dimensions be multiplied four 
 times, the strength will be multiplied sixteen times, and the 
 weight sixty-four times, and so on. 
 
 Hence it is obvious, that although the strength of a body 
 of small dimensions may greatly exceed its weight, and, 
 therefore, it may be able to support a load many times its 
 own weight, yet by a great increase in the dimensions, the 
 weight increasing in a much greater degree, the available 
 strength must be much diminished, and such a magnitude 
 may be assigned, that the weight of the body must exceed its 
 strength, and it not only would be unable to support any load, 
 but would actually fall to pieces by its own weight. 
 
 The strength of a structure of any kind is not, therefore, 
 to be determined by that of its model, which will always be 
 much stronger in proportion to its size. All works, natural 
 and artificial, have limits of magnitude which, while their 
 materials remain the same, they cannot surpass. 
 
 In conformity with what has just been explained, it has 
 been observed, that small animals are stronger in proportion 
 than large ones; that the young plant has more available 
 strength in proportion than the large forest tree ; that chil- 
 dren are less liable to injury from accident than men, &-c. 
 But although, to a certain extent, these observations are just, 
 20* 
 
234 THE ELEMENTS OF MECHANICS. CHAP. XXI 
 
 yet it ought not to be forgotten, that the mechanical conclu- 
 sions which they are brought to illustrate are founded on the 
 supposition, that the smaller and greater bodies which are 
 compared are composed of precisely similar materials. This 
 is not the case in any of the examples here adduced. 
 
 CHAPTER XXI. 
 
 ON BALANCES AND PENDULUMS. 
 
 335.) THE preceding chapters have been confined almost 
 wholly to the consideration of the laws of mechanics, without 
 entering into a particular description of the machinery and 
 instruments dependent upon those laws. Such descriptions 
 would have interfered too much with the regular progress of 
 the subject, and it therefore appeared preferable to devote a 
 chapter exclusively to this portion of the work. 
 
 Perhaps there are no ideas which man receives through 
 the medium of sense which may not be referred ultimately to 
 matter and motion. In proportion, therefore, as he becomes 
 acquainted with the properties of the one and the laws of the 
 other, his knowledge is extended ; his comforts are multiplied ; 
 lie is enabled to bend the powers of nature to his will, and 
 to construct machinery which effects with ease that which 
 the united labor of thousands would in vain be exerted to 
 accomplish. 
 
 Of the properties of matter, one of the most important is 
 its weight ; and the element which mingles inseparably with 
 the laws of motion is time. 
 
 In the present chapter, it is our intention to describe such 
 instruments as are usually employed for determining the 
 weight of bodies. To attempt a description of the various 
 machines which are used for the measurement of time, would 
 lead us into too wide a field for the present occasion, and 
 we shall, therefore, confine ourselves to an account of the 
 methods which have been practised to perfect that instrument 
 which affords the most correct means of measuring time the 
 pendulum. 
 
 The instrument by which we are enabled to determine, 
 with greater accuracy than by any other means, the relative 
 
CHAP. XXI. THE BALANCE. 235 
 
 weight of a body, compared with the weight of another body 
 assumed as a standard, is the balance. 
 
 Of the Balance. 
 
 The balance may be described as consisting of an inflexi- 
 ble rod or lever, called the beam, furnished with three axes ; 
 one, the fulcrum or centre of motion, situated in the middle, 
 upon which the beam turns, and the other two near the ex- 
 tremities, and at equal distances from the middle. These 
 last are called the points of support, and serve to sustain the 
 pans or scales. 
 
 The points of support and the fulcrum are in the same 
 right line, and the centre of gravity of the whole should be 
 a little below the fulcrum when the position of the beam is 
 hodzont il. 
 
 The arms of the lever being equal, it follows that if equal 
 weights be put into the scales, no effect will be produced on 
 the position of the balance, and the beam will remain hori- 
 zontal. 
 
 If a small addition be made to the weight in one of the 
 scales, the horizontality of the beam will be disturbed ; and 
 after oscillating for some time, it will, on attaining a state of 
 rest, form an angle with the horizon, the extent of which is 
 a measure of the delicacy or sensibility of the balance. 
 
 As the sensibility of a balance is of the utmost importance 
 in nice scientific inquiries, we shall enter somewhat at large 
 into a consideration of the circumstances by which this prop- 
 erty is influenced. 
 
 In Jig. 187. let A B represent the beam drawn from the 
 horizontal position by a very small weight placed in the scale 
 suspended from the point of support B ; then the force tend- 
 ing to draw the beam from the horizontal position may be 
 expressed by P B multiplied by such very small weight acting 
 upon the point B. 
 
 Let the centre of gravity of the whole be at G ; then the 
 force acting against the former will be G P multiplied into 
 the weight of the beam and scales, and when these forces 
 are equal, the beam will rest in arv inclined position. Hence 
 we may perceive that as the centre of gravity is nearer to or 
 further from the fulcrum S, (every thing else remaining the 
 same,) the sensibility of the balance will be increased or 
 diminished. 
 
236 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 For, suppose the centre of gravity were removed to g ; 
 then, to produce an opposing force equal to that acting upon 
 the extremity of the beam, the distance g p from the perpen- 
 dicular line must be increased until it becomes nearly equal 
 to G P ; but for this purpose the end of the beam B must 
 descend, which will increase the angle II S B. 
 
 As all weights placed in the scales are referred to the line 
 joining the points of support, and as this line is above the 
 centre of gravity of the beam when not loaded, such weights 
 will raise the centre of gravity ; but it will be seen that the 
 sensibility of the balance, as far as it depends upon this 
 cause, will remain unaltered. 
 
 For, calling the distance S G unity, the distance of the 
 centre of gravity from the point S (to which the weight 
 which has been added is referred) will be expressed by the 
 reciprocal of the weight of the beam so increased ; that is, 
 if the weight of the beam be doubled by weights placed in 
 the scales, S g will be one half of S G ; and if the weight 
 of the beam be in like manner trebled, S g will be one third 
 of S G, and so on. And as G P varies as S G, g p will be 
 inversely proportionate to the increased weight of the beam, 
 and, consequently, the product obtained by multiplying g p 
 by the weight of the beam and its load will be a constant 
 quantity, and the sensibility of the balance, as before stated, 
 will suffer no alteration. 
 
 We will now suppose that the fulcrum S,Jig. 188., is situ- 
 ated below the line joining the points of support, and that 
 the centre of gravity of the beam when not loaded is at G ; 
 also that when a very small weight is placed in the scale 
 suspended from the point B, the beam is drawn from its hor- 
 izontal position, the deviation being a measure of the sensi- 
 bility of the balance. Then, as before stated, G P multiplied 
 by the weight of the beam will be equal to P' B multiplied 
 by the very small additional weight acting on the point B. 
 
 Now, if we place equal weights in both scales, such addi- 
 tional weights will be referred to the point W, and the result- 
 ing distance of the centre of gravity from the point W, 
 calling W G unity, will be expressed as before by the recip- 
 rocal of the increased weight of the loaded beam, But G P 
 will decrease in a greater proportion than W G : thus, sup- 
 posing the weight of the beam to be doubled, W g would be 
 one half of W G ; but g p, as will be evident on an inspec- 
 tion of the figure, will be less than half of G P ; and the 
 
CHAP. XXI. THE BALANCE. 237 
 
 same small weight which was before applied to the point B, 
 if now added, would depress the point B, until the distance 
 g p became such as that, when multiplied by the weight of 
 the whole, the product would be as before equal to P' B mul- 
 tiplied by the before mentioned very small added weight. 
 The sensibility of the balance, therefore, in this case, would 
 be increased. 
 
 If the beam be sufficiently loaded, the centre of gravity 
 will at length be raised to the fulcrum S, and the beam will 
 rest indifferently in any position. If more weight be then 
 added, the centre of gravity will be raised above the fulcrum, 
 and the beam will turn over. 
 
 Lastly, if the fulcrum S,Jig. 189., is above the line joining 
 the two points of support, as any additional weights placed 
 in the scales will be referred to the point W, in the line 
 joining A and B, if the weight of the beam be doubled by 
 such added weights, and the centre of gravity be consequent- 
 ly raised to g, W g will become equal to half of W G. But 
 g p, being greater than one half of G P, the end of the 
 beam B will rise until g p becomes such as to be equal, when 
 multiplied by the whole increased weight of the beam, to 
 P B, multiplied by the small weight which we suppose to 
 have been placed as in the preceding examples, in the 
 scale. 
 
 From what has been said, it will be seen that there are 
 three positions of the fulcrum which influence the sensibility 
 of the balance ; first, when the fulcrum and the points of 
 support are in a right line, when the sensibility of the bal- 
 ance will remain the same, though the weight with which 
 the beam is loaded should be varied; secondly, when the ful- 
 crum is below the line joining the two points of support, in 
 which case the sensibility of the balance will be increased by 
 additional weights, until at length the centre of gravity is 
 raised above the fulcrum, when the beam will turn over ; 
 and, thirdly, when the fulcrum is above the line joining the 
 two points of support, in which case the sensibility of the 
 balance will be diminished as the weight with which the 
 beam is loaded is increased. 
 
 The sensibility of a balance, as here defined, is the angu- 
 lar deviation of the beam occasioned by placing an additional 
 constant small weight in one of the scales ; but it is frequent- 
 ly expressed by the proportion which such small additional 
 weight bears to the weight of the beam and its load, and 
 
238 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 sometimes to the weight the value of which is to be deter- 
 mined. 
 
 This proportion, however, will evidently vary with different 
 weights, except in the case where the centre of gravity of the 
 beam is in the line joining the points supporting the scales, the 
 fulcrum being above this line ; and it is therefore necessary, 
 in every other case, when speaking of the sensibility of the 
 balance, to designate the weight with which it is loaded ; 
 thus, if a balance has a troy pound in each scale, and the 
 horizontally of the beam varies a certain small quantity, just 
 perceptible on the addition of one hundredth of a grain, we 
 say that the balance is sensible to Ty-g^innr part of its load 
 with a pound in each scale, or that it will determine the 
 weight of a troy pound within ^y^Voir P art f tne whole. 
 
 The nearer the centre of gravity of a balance is to its 
 fulcrum, the slower will be the oscillations of the beam. 
 The number of oscillations, therefore, made by the beam in 
 a given time (a minute for example), affords the most accu- 
 rate method of judging of the sensibility of the balance, 
 which will be the greater as the oscillations are fewer. 
 
 Balances of the most perfect kind (and of such only it is 
 our present object to treat) are usually furnished with adjust- 
 ments, by means of which the length of the arms, or the 
 distances of the fulcrum from the points of support, may be 
 equalized, and the fulcrum and the two points of support be 
 placed in a right line ; but these adjustments, as will hereaf- 
 ter be seen, are not absolutely necessary. 
 
 The beam is variously constructed, according to the pur- 
 poses to which the balance is to be applied. Sometimes it is 
 made of a rod of solid steel ; sometimes of two hollow cones 
 joined at their bases ; and, in some balances, the beam is a 
 frame in the form of a rhombus ; the principal object in all, 
 however, is to combine strength and inflexibility with light- 
 ness. 
 
 A balance of the best kind, made by Troughton, is so 
 contrived as to be contained, when not in use, in a drawer 
 below the case ; and when in use, it is protected from any 
 disturbance from currents of air, by being enclosed in the 
 case above the drawer, the back and front of which are of 
 plate glass. There are doors in the sides, through which 
 the scale-pans are loaded, and there is a door at the top 
 through which the beam may be taken out. 
 
 A strong brass pillar, in the centre of the box, supports a 
 

 CHAP. xxi. TROUGIITON'S AND ROBINSON'S BALANCES. 239 
 
 square piece, on the front and back of which rise two arches, 
 nearly semicircular, on which are fixed two horizontal planes 
 of agate, intended to support the fulcrum. Within the pillar 
 is a cylindrical tube, which slides up and down by means of 
 a handle on the outside of the case. To the top of this in- 
 terior tube is fixed an arch, the terminations of which pass 
 beneath and outside of the two arches before described. 
 These terminations are formed into Y 5, destined to receive 
 the ends of the fulcrum, which are made cylindrical for this 
 purpose, when the interior tube is elevated in order to relieve 
 the axis when the balance is not in use. On depressing the 
 interior tube, the Y s quit the axis, and leave it in its proper 
 position on the agate planes. The beam is about eighteen 
 inches long, and is formed of two hollow cones of brass, 
 joined at their bases. The thickness of the brass does not 
 exceed 0-02 of an inch, but by means of circular rings driven 
 into the cones at intervals, they are rendered almost inflexible. 
 Across the middle of the beam passes a cylinder of steel, the 
 lower side of which is formed into an edge, having an angle 
 of about thirty degrees, which, being hardened and well pol- 
 ished, constitutes the fulcrum, and rests upon the agate 
 planes for the length of about 0-05 of an inch. 
 
 Each point of suspension is formed of an axis having two 
 sharp concave edges, upon which rest at right angles two 
 other sharp concave edges formed in the spur-shaped piece to 
 which the strings carrying the scale-pan are attached. The 
 two points are adjustable, the one horizontally, for the pur- 
 pose of equalizing the arms of the beam, and the other ver- 
 tically, for bringing the points of suspension and the fulcrum 
 into a right line. 
 
 Such is the form of Troughton's balance. We shall now 
 give the description of a balance as constructed by Mr. Rob- 
 inson of Devonshire Street, Portland Place : 
 
 The beam of this balance is only ten inches long. It is a 
 frame of bell-metal in the form of a rhombus. The fulcrum 
 is an equilateral triangular prism of steel one inch in length ; 
 but the edge on which the beam vibrates is formed to an 
 angle of 120, in order to prevent any injury from the weight 
 with which it may be loaded. The chief peculiarity in this 
 balance consists in the knife-edge which forms the fulcrum 
 bearing upon an agate plane throughout its whole length, 
 whereas we have seen in the balance before described that 
 the whole weight is supported by portions only of the knife- 
 
240 THE ELEMENTS OP MECHANICS. CHAP. XXI 
 
 edge, amounting together to one tenth of an inch. The sup- 
 ports for the scales are knife-edges, each six tenths of an inch 
 long. These are each furnished with two pressing screws, 
 by means of which they may be made parallel to the central 
 knife-edge. 
 
 Each end of the beam is sprung obliquely upwards and 
 towards the middle, so as to form a spring through which a 
 pushing screw passes, which serves to vary the distance of 
 the point of support from the fulcrum, and, at the same time, 
 by its oblique action, to raise or depress it, so as ,o furnish a 
 means of bringing the points of support and the fulcrum into 
 a right line. 
 
 A piece of wire, four inches long, on which a screw is cut, 
 proceeds from the middle of the beam downvyards. This is 
 pointed to serve as an index, and a small brass ball moves on 
 the screw, by changing the situation of which the place of 
 the centre of gravity may be varied at pleasure. 
 
 The fulcrum, as before remarked, rests upon an agate plane 
 throughout its whole length, and the scale-pans are attached 
 to planes of agate which rest upon the knife-edges forming 
 the points of support. This method of supporting the scale- 
 pans, we have reason to believe, is due to Mr. Cavendish. 
 Upon the lower half of the pillar to which the agate plane is 
 fixed, a tube slides up and down by means of a lever which 
 passes to the outside of the case. From the top of this tube 
 arms proceed obliquely towards the ends of the balance, serv- 
 ing to support a horizontal piece, carrying at each extremity 
 two sets of Y s, one a little above the other. The upper Y 5 
 are destined to receive the agate planes to which the scale- 
 pans are attached, and thus to relieve the knife-edges from 
 their pressure ; the lower to receive the knife-edges which 
 form the points of support, consequently these latter Y s, 
 when in action, sustain the whole beam. 
 
 When the lever is freed from a notch in which it is lodged, 
 a spring is allowed to act upon the tube we have mentioned, 
 and to elevate it. The upper Y s first meet the agate planes 
 carrying the scale-pans, and free them from the knife-edges. 
 The lower Y s then come into action, and raise the whole 
 beam, elevating the central knife-edge above the agate plane. 
 This is the usual state of the balance when not in use : when 
 it is to be brought into action, the reverse of what we have 
 described takes place. On pressing down the lever, the cen- 
 tral knife-edge first meets the agate plane, and afterwards the 
 
CHAP. xxi. KATER'S BALANCE. 241 
 
 two agate planes carrying the scale-pans are deposited upon 
 their supporting knife-edges. 
 
 A balance of this construction was employed by the writer 
 of this article in adjusting the national standard pound. With 
 a pound troy in each scale, the addition of one hundreth of a 
 grain caused the index to vary one division, equal to one tenth 
 of an inch, and Mr. Robinson adjusts these balances so that 
 with one thousand grains in each scale, the index varies per- 
 ceptibly on the addition of one thousandth of a grain, or of 
 one millionth part of the weight to be determined. 
 
 It may not be uninteresting to subjoin, from the Philo- 
 sophical Transactions for 1826, the description of a balance 
 perhaps the most sensible that has yet been made, construct- 
 ed for verifying the national standard bushel. The author 
 says, 
 
 " The weight of the bushel measure, together with the 80 
 Ibs. of water it should contain, was about 250 Ibs. ; and as I 
 could find no balance capable of determining so large a weight 
 with sufficient accuracy, I was under the necessity of con- 
 structing one for this express purpose. 
 
 " I first tried cast iron ; but though tke beam was made as 
 light as was consistent with the requisite degree of strength, 
 the inertia of such aMiass appeared to be so considerable, 
 that much time must have been lost before the balance would 
 have answered to the small differences I wished to ascertain. 
 Lightness was a property essentially necessary, and bulk was 
 very desirable, in order to preclude such errors as might arise 
 from the beam being partially affected by sudden alterations 
 of temperature. I therefore determined to employ wood, a 
 material in which the requisites I sought were combined. 
 The beam was made of a plank of mahogany, about 70 
 inches long, 22 inches wide, and 2 thick, tapering from the 
 middle to the extremities. An opening was cut in the centre, 
 and strong blocks screwed to each side of the plank, to form 
 a bearing for the back of a knife-edge which passed through 
 the centre. Blocks were also screwed to each side at the 
 extremities of the beam, on which rested the backs of the 
 knife-edges for supporting the pans. The opening in the 
 centre was made sufficiently large to admit the support 
 hereafter to be described, upon which the knife-edge rested. 
 
 " In all beams which I have seen, with the exception of 
 those made by Mr. Robinson, the whole weight is sustained 
 by short portions at the extremities of the knife-edge ; and 
 21 
 
242 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 the weight being thus thrown ftpon a few points, the knife- 
 edge becomes more liable to change its figure and to suffer 
 injury. 
 
 " To remedy this defect, the central knife-edge of the beam 
 I am describing was made 6 inches, and the two others 5 
 inches long. They were triangular prisms with equal sides of 
 three fourths of an inch, very carefully finished, and the edges 
 ultimately formed to an angle of 120. 
 
 " Each knife-edge was screwed to a thick plate of brass, 
 the surfaces in contact having been previously ground togeth- 
 er ; and these plates were screwed to the beam, the knife- 
 edges being placed in the same plane, and as nearly equidis- 
 tant and parallel to each other as could be done by construction. 
 
 " The support upon which the central knife-edge rested 
 throughout its whole length was formed of a plate of polished 
 hard steel, screwed to a block of cast iron. This block was 
 passed through the opening before mentioned in the centre 
 of the beam, and properly attached to a frame of cast iron. 
 
 " The stirrups to which the scales were hooked, rested 
 upon plates of polished steel to which they were attached, 
 and the under surfaces of which were formed by careful grind- 
 ing into cylindrical segments. These were in contact with 
 the knife-edges their whole length, and were known to be in 
 their proper position by the correspondence of their extremi- 
 ties with those of the knife-edges. A well imagined con- 
 trivance was applied by Mr. Bate for raising the beam when 
 loaded, in order to prevent unnecessary wear of the knife- 
 edge, and for the purpose of adjusting the place of the centre 
 of gravity, when the beam was loaded with the weight re- 
 quired to be determined, a screw carrying a movable ball pro- 
 jected vertically from the middle of the beam. 
 
 " The performance of this balance fully equalled my ex- 
 pectations. With two hundred and fifty pounds in each scale, 
 the addition of a single grain occasioned an immediate varia- 
 tion in the index of one twentieth of an inch, the radius being 
 fifty inches." 
 
 From the preceding account, it appears that this balance is 
 sensible to yTF&innr P art f tne weight which was to be de- 
 termined. 
 
 We shall now describe the method to be pursued in adjust- 
 ing a balance. 
 
 1. To bring the points of suspension and the fulcrum into 
 a right line. 
 
CHAP. XXI. USE OF THE BALANCE. 243 
 
 Make the vibrations of the balance very slow, by moving 
 the weight which influences the centre of gravity, and bring 
 the beam into a horizontal position, by means of small bits 
 of paper thrown into the scales. Then load the scales with 
 nearly the greatest weight the beam is fitted to carry. If the 
 vibrations are performed in the same time as before, no fur- 
 ther adjustment is necessary ; but if the beam vibrates quick- 
 er, or if it oversets, cause it to vibrate in the same time as at 
 first, by moving the adjusting weight, and note the distance 
 through which the weight has passed. Move the weight then 
 in the contrary direction through double this distance, and 
 then produce the former slow motion by means of the screw 
 acting vertically on the point of support. Repeat this opera- 
 tion until the adjustment is perfect. 
 
 2. To make the arms of the beam of an equal length. 
 
 Put weights in the scales as before; bring the beam as 
 nearly as possible to a horizontal position, and note the divis- 
 ion at which the index stands ; unhook the scales, and trans- 
 fer them with their weights to the other ends of the beam, 
 when, if the index points to the same division, the arms are 
 of an equal length ; but if not, bring the index to the division 
 which had been noted, by placing small weights in one or the 
 other scale. Take away half these weights, and bring the 
 index again to the observed division by the adjusting screw, 
 which acts horizontally on the point of support. If the scale- 
 pans are known to be of the same weight, it will not be ne- 
 cessary to change the scales,'but merely to transfer the weights 
 from one scale-pan to the other. 
 
 Of the Use of the Balance. 
 
 Though we have described the method of adjusting the 
 balance, these adjustments, as we have before remarked, may 
 be dispensed with. Indeed, in all delicate scientific opera- 
 tions, it is advisable never to rely upon adjustments, which, 
 after every care has been employed in effecting them, can 
 only be considered as approximations to the truth. We shall, 
 therefore, now describe the best method of ascertaining the 
 weight of a body, and which does not depend on the accura- 
 cy of these adjustments. 
 
 Having levelled the case which contains the balance, and 
 thrown the beam out of action, place a weight in each scale- 
 pan nearly equal to the weight which is to be determined. 
 
244 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 Lower the beam very gently till it is in action, and, by means 
 of the adjustment for raising or lowering the centre of gravi- 
 ty, cause the beam to vibrate very slowly. Remove these 
 weights, and place the substance, the weight of which is to 
 be determined, in one of the scale-pans; carefully counter- 
 pose it by means of any convenient substances put into the 
 other scale-pan, and observe the division at which the index 
 stands ; remove the body, the weight of which is to be ascer- 
 tained, and substitute standard weights for it so as to bring 
 the index to the same division as before. These weights will 
 be equal to the weight of the body. 
 
 If it be required to compare two weights together which 
 are intended to be equal, and to ascertain their difference, if 
 any, the method of proceeding will be nearly the same. The 
 standard weight is to be carefully counterpoised, and the divis- 
 ion at which the index stands, noted. And now it will be 
 convenient to add in either of the scales some small weight, 
 such as one or two hundredths of a grain, and mark the num- 
 ber of divisions passed over in consequence by the index, by 
 which the value of one division of the scale will be known. 
 This should be repeated a few times, and the mean taken for 
 greater certainty. 
 
 Having noted the division at which the index rests, the 
 standard weight is to be removed, and the weight which is to 
 be compared with it substituted for it. The index is then 
 again to be noted, and the difference between this and the 
 former indication will give the difference between the weights 
 in parts of a grain. 
 
 If the balance is adjusted so as to be very sensible, it will 
 be long before it comes to a state of rest. It may, therefore, 
 sometimes be advisable to take the mean of the extent of the 
 vibrations of the index as the point where it would rest, and 
 this may be repeated several times for greater accuracy. It 
 must, however, be remembered, that it is not safe to do this 
 when the extent of the vibrations is beyond one or two divis- 
 ions of the scale ; but with this limitation, it is, perhaps, as 
 good a method as can be pursued. 
 
 Many precautions are necessary to ensure a satisfactory 
 result. The weights should never be touched by the hand ; 
 for not only would this oxydate the weight, but by raising its 
 temperature it would appear lighter, when placed in the scale 
 pan, than it should do, in consequence of the ascent of the 
 liented air. For the larger weights, a wooden fork or tongs, 
 
CHAP. XXI. WEIGHTS. 245 
 
 according to the form of the weight, should be employed ; 
 and for the smaller, a pair of forceps made of copper will be 
 found the most convenient ; this metal possessing sufficient 
 elasticity to open the forceps on their being released from 
 pressure, and yet not opposing a resistance sufficient to in- 
 terfere with that delicacy of touch which is desirable in such 
 operations. 
 
 Of Weights. 
 
 It must be obvious, that the excellence of the balance would 
 be of little use, unless the weights employed were equally to 
 be depended upon. The weights may either be accurately 
 adjusted, or the difference between each weight and the 
 standard may be determined, and, consequently, its true 
 value ascertained. It has been already shown how the latter 
 may be effected, in the instructions which have been given 
 for comparing two weights together ; and we shall now show 
 the readiest mode of adjusting weights to an exact equality with 
 a given standard. 
 
 The material of the weight may be either brass or platina, 
 and its form may be cylindrical ; the diameter being nearly 
 twice the height. A small spherical knob is screwed into 
 the centre, a space being left under the screw to receive the 
 portions of fine wire used in the adjustment. It will be con- 
 venient to form a cavity in the bottom of each weight, to re- 
 ceive the knob of the weight upon which it may be placed. 
 
 Each weight is now to be compared with the standard, and 
 should it be too heavy, it is to be reduced till it becomes in a 
 very small degree too light, when the amount of the deficien- 
 cy is to be carefully determined. 
 
 Some very fine silver wire is now to be taken, and the 
 weight of three or four feet of it ascertained. From this it 
 will be known what length of the wire is equal to the error 
 of the weight to be adjusted; and this length being cut off 
 is to be enclosed under the screw. To guard against any 
 possible error, it will be advisable, before the screw is firm- 
 ly fixed in its place, again to compare the weight with the 
 standard. 
 
 The most approved method of making weights expressing 
 the decimal parts of a grain, is to determine, as before, with 
 great care, the weight of a certain length of fine wire, and 
 then to cut off such portions as are equal to the weights re- 
 quired. 
 
 21 * 
 
246 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 Before we conclude this article, we shall give a description, 
 from the Annals of Philosophy for 1825, of " a very sensible 
 balance," used by the late Dr. Black : 
 
 " A thin piece of fir wood, not thicker than a shilling, and 
 a foot long, three tenths of an inch broad in the middle, and 
 one tenth and a half at each end, is divided by transverse 
 lines into twenty parts ; that is, ten parts on each side of the 
 middle. These are the principal divisions, and each of them 
 is subdivided into halves and quarters. Across the middle is 
 fixed one of the smallest needles 1 could procure, to serve as 
 an axis, and it is fixed in its place by means of a little sealing 
 wax. The numeration of the divisions is from the middle to 
 each end of the beam. The fulcrum is a bit of plate bra^s, 
 the middle of which lies flat on my table when I use the bal- 
 ance, and the two ends are bent up to a right angle so as to 
 stand upright. These two ends are ground at the same time 
 on a flat hone, that the extreme surfaces of them may be in the 
 same plane ; and their distance is such that the needle, when 
 laid across them, rests on them at a small distance from the 
 sides of the beam. They rise above the surface of the table 
 only one tenth and a half, or two tenths of an inch, so that 
 the beam is very limited in its play. See Jig. 190. 
 
 " The weights I use are one globule of gold, which weighs 
 one grain, and two or three others which weigh one tenth of 
 a grain each ; and also a number of small rings of fine brass 
 wire, made in the manner first mentioned by Mr. Lewis, by 
 appending a weight to the wire, and coiling it with the ten- 
 sion of that weight round a thicker brass wire in a close spiral, 
 after which, the extremity of the spiral being tied hard with 
 waxed thread, I put the covered wire into a vice, and apply- 
 ing a sharp knife, which is struck with a hammer, I cut 
 through a great number of the coils at one stroke, and find 
 them as exactly equal to one another as can be desired. Those 
 I use happen to be the ^ part of a grain each, or 300 of 
 them weigh ten grains ; but I have others much lighter. 
 
 " You will perceive that, by means of these weights placed 
 on different parts of the beam, I can learn the weight of any 
 little mass from one grain, or a little more, to the T5 -Vir f a 
 grain. For if the thing to be weighed weighs one grain, it 
 will, when placed on one extremity of the beam, counterpoise 
 the large gold weight at the other extremity. If it weighs 
 half a grain, it will counterpoise the heavy gold weight placed 
 at 5. If it weigh T 6 a of a grain, you must place the heavy gold 
 
CHAP. XXT. DR. BLACK'S BALANCE. 247 
 
 weight at 5, and one of the lighter ones at the extremity to 
 counterpoise it ; and if it weighs only one or two, or three or 
 four hundredths of a grain, it will be counterpoised by one of 
 the small gold weights placed at the first or second, or third 
 or fourth division. If, on the contrary, it weighs one grain 
 and a fraction, it will be counterpoised by the heavy gold 
 weight at the extremity, and one or more of the lighter ones 
 placed in some other part of the beam. 
 
 " This beam has served me hitherto for every purpose ; but 
 had I occasion for a more delicate one, I could make it easily 
 by taking a much thinner and lighter slip of wood, and grind- 
 ing the needle to give it an edge. It would also be easy to 
 make it carry small scales of paper for particular purposes." 
 
 The writer of this article has used a balance of this kind, 
 and finds that it is sensible to ^JTT f a grain when loaded 
 with ten grains. It is necessary, howerer, where accuracy 
 is required, to employ a scale-pan. This may be made of 
 thin card paper, shaped as in Jig. 191. 
 
 A thread is to be passed through the two ends, by tighten- 
 ing which they may be brought near each other. 
 
 The most convenient weights for this beam appear to be 
 two of one grain each, and one of one tenth of a grain. 
 They .should be made of straight wire ; and if the beam be 
 notched at the divisions, they may be lodged in these notches 
 very conveniently. Ten divisions on each side of the middle 
 will be sufficient. The weight of the scale-pan must first be 
 carefully ascertained, in order that it may be deducted from 
 the weight, afterwards determined, of the scale-pan and the 
 substance it may contain. 
 
 If the scale-pan be placed at the tenth division of the 
 beam, it is evident that by means of the two grain weights, 
 a greater weight cannot be determined than one grain and 
 nine tenths ; but if the scale-pan be placed at any other 
 division of the beam, the resulting apparent weight must be 
 increased by multiplying it by ten, and dividing by the num- 
 ber of the division at which the scale-pan is placed ; and 
 in this manner it is evident that if the scale-pan be placed at 
 the division numbered 1, a weight amounting to nineteen 
 grains may be determined. 
 
 We have been tempted to describe this little apparatus 
 because it is extremely simple in its construction, may be 
 easily made, and may be very usefully employed on many 
 occasions where extreme accuracy is not necessary. 
 
248 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 Description of the Steelyard. 
 
 Thn steelyard is a lever, having unequal arms ; and in its 
 most simple form it is so arranged, that one weight alone 
 serves to determine a great variety of others, by sliding it 
 along the longer arm of the lever, and thus varying its dis- 
 tance from the fulcrum. 
 
 It has been demonstrated, Chapter XIII., that in the lever 
 the proportion of the power to the weight will be always the 
 same as that of their distances from the fulcrum, taken in a 
 reverse order ; consequently, when a constant weight is used, 
 and an equilibrium established by sliding this weight on the 
 longer arm of the lever, the relative weight of the substance 
 weighed, to the constant weight, will be in the same propor- 
 tion as the distance of the constant weight from the fulcrum 
 is to the length of the shorter arm. 
 
 Thus, suppose the length of the shorter arm, or the distance 
 of the fulcrum from the point from which the weight to be 
 determined is suspended, to be one inch ; let the longer arm 
 of the lever be divided into parts of one inch each, begin- 
 ning at the fulcrum. Now let the constant weight be equal 
 to one pound, and let the steelyard be so constructed that 
 the shorter arm shall be sufficiently heavy to counterpoise 
 the longer when the bar is unloaded. Then suppose a sub- 
 stance, the weight of which is five pounds, to be suspended 
 from the shorter arm. It will be found that when the con- 
 stant weight is placed at the distance of five inches from the 
 fulcrum, the weights will be in equilibrium, and the bar 
 consequently horizontal. In this steelyard, therefore, the 
 distance of each inch from the fulcrum indicates a weight 
 of one pound. An instrument of this form was used by the 
 Romans, and it is usually described as the Roman statera or 
 steelyard. A representation of it is given at Jig. 192. 
 
 The steelyard is in very general use for the coarser pur- 
 poses of commerce, but constructed differently from that 
 which we have described. The beam with the scales or 
 hooks is seldom in equilibrium upon the point F, when the 
 weight P is removed ; but the longer arm usually preponder- 
 ates, and the commencement of the graduations, therefore, 
 is not at F, but at some point between B and F. The com- 
 mon steelyard, which we have represented at Jig. 193., is 
 usually furnished with two points, from either of which the 
 substance, the weight of which is to be determined, may be 
 
CHAP. xxi. c. PAUL'S STEELYARD. 249 
 
 suspended. The value of the divisions is in this case in- 
 creased in proportion as the length of the shorter arm is 
 decreased. Thus, in the steelyard which we have described, 
 if there be a second point of suspension at the distance 
 of half an inch from the fulcrum, each division of the longer 
 arm will indicate two pounds instead of one, and these di- 
 visions are usually marked upon the opposite edge of the 
 steelyard, which is made to turn over. 
 
 This instrument is very convenient, because it requires 
 but one weight ; and the pressure on the fulcrum is less than 
 in the balance, when the substance to be weighed is heavier 
 than the constant weight. But, on the contrary, when the 
 constant weight exceeds the substance to be weighed, the 
 pressure on the fulcrum is greater in the steelyard than in 
 the balance, and the balance is, therefore, preferable in de- 
 termining small weights. There is also an advantage in the 
 balance, because the subdivision of weights can be effected 
 with a greater degree of precision than the subdivision of 
 the arm of the steelyard. 
 
 C. Pau?s Steelyard. 
 
 A steelyard has been constructed by Mr. C. Paul, inspector 
 of weights and measures at Geneva, which is much to be pre- 
 ferred to that in common use. Mr. C. Paul states, that steel- 
 yards have two advantages over balances : 1. That their axis 
 of suspension is not loaded with any other weight than that 
 of the merchandise, the constant weight of the apparatus 
 itself excepted ; while the axis of the balance, besides the 
 weight of the instrument, sustains a weight double to that of 
 the merchandise. 2. The use of the balance requires a con- 
 siderable assortment of weights, which causes a proportional 
 increase in the price of the apparatus, independently of the 
 chances of error which it multiplies, and of the time employ- 
 ed in producing an equilibrium. 
 
 1. In C. Paul's steelyard, the centres of the movement of 
 suspension, or the two constant centres, are placed on the 
 exact line of the divisions of the beam ; an elevation almost 
 imperceptible in the axis of the beam, destined to compensate 
 for the very slight flexion of the bar, alone excepted. 
 
 2. The apparatus, by the construction of the beam, is bal- 
 anced below its centre of motion, so that when no weight is 
 suspended, the beam naturally remains horizontal, and re- 
 
250 THE ELEMEN 7 TS OF MECHANICS. CHAP. XXI. 
 
 sumes that position when removed from it, as also when the 
 steelyard is loaded, and the Aveight is at the division which 
 ought to show how much the merchandise weighs. The hor- 
 izontal situation in this steelyard, as well as in the others, is 
 known by means of the tongue, which rises vertically above 
 the axis of suspension. 
 
 3. It may be discovered that the steelyard is deranged, if, 
 when not loaded, the beam does not remain horizontal. 
 
 4. The advantage of a great and a small side (which in the 
 other augments the extent of their power of weighing) is sup- 
 plied by a very simple process, which accomplishes the same 
 end with some additional advantages. This process is to em- 
 ploy on the same division different weights. The numbers of 
 the divisions on the bar point out the degree of heaviness ex- 
 pressed by the corresponding weights. For example, when 
 the large weight of the large steelyard weighs 16 Ibs., 
 each division it passes over on the bar is equivalent to a 
 pound ; the small weight, weighing sixteen times less than 
 the large one, will represent on each of these divisions the 
 sixteenth part of a pound, or one ounce ; and the opposite 
 face of the bar is marked by pounds at each sixteenth divis- 
 ion. In this construction, therefore, we have the advan- 
 tage of being able, by employing both weights at once, to 
 ascertain, for example, almost within an ounce, the weight of 
 500 pounds of merchandise. It will be sufficient to add 
 what is indicated by the small weight in ounces, to that of 
 the large one in pounds, after an equilibrium has been obtain- 
 ed by the position of the two weights, viz. the large one placed 
 at the next pound below its real weight, and the small one 
 at the division which determines the number of ounces to be 
 added. 
 
 5. As the beam is graduated only on one edge, it may 
 have the form of a thin bar, which renders it much less 
 susceptible of being bent by the action of the weight, and 
 affords room for making the figures more visible on both the 
 faces. 
 
 6. In these steelyards, the disposition of the axes is not only 
 such that the beam represents a mathematical lever without 
 weight, but in the principle of its division, the interval be- 
 tween every two divisions is a determined and aliquot part of 
 the distance between the two fixed points of suspension ; and 
 each of the two weights employed has for its absolute weight 
 the unity of the weight it represents, multiplied by the num 
 

 CHAP. xxi. c. PAUL'S STEELYARD. 251 
 
 ber of the divisions contained in the interval between the two 
 centres of motion. 
 
 Thus, supposing the arms of the steelyard divided in such 
 a manner that ten divisions are exactly contained in the dis- 
 tance between the two constant centres of motion, a weight 
 to express the pounds on each division of the beam, must 
 really weigh ten pounds ; that to point out the ounces on the 
 same divisions must weigh ten ounces, &,c. ; so that the same 
 steelyard may be adapted to any system of measures whatever, 
 and in particular to the decimal system, by varying the ab- 
 solute heaviness of the weights, and their relation with each 
 other. 
 
 But to trace out, in a few words, the advantages of the steel- 
 yards constructed by C. Paul for commercial purposes, we 
 shall only observe, 
 
 1. That the buyer and seller are certain of the correctness 
 of the instrument, if the beam remains horizontal when it is 
 unloaded and in its usual position. 2. That these steelyards 
 have one suspension less than the old ones, and are so much 
 more simple. 3. That by these means we obtain, with the 
 greatest facility, by employing two weights, the exact weight of 
 merchandise, with all the approximation that can be desired, 
 and even with a greater precision than that given by common 
 balances. There are few of these which, when loaded with 
 500 pounds at each end, give decided indication of an ounce 
 variation ; and the steelyards of C. Paul possess that advan- 
 tage, and cost one half less than balances of equal dominion. 
 4. In the last place, we may verify at pleasure the justness of 
 the weights, by the transposition which their ratio to each 
 other will permit ; for example, by observing whether, when 
 the weight of one pound is brought back one division, and 
 the weight of one ounce carried forward sixteen divisions, the 
 equilibrium still remains. 
 
 It is on this simple and advantageous principle that C. Paul 
 has constructed his universal steelyard. It serves for weigh- 
 ing in the usual manner, and according to any system of 
 weights, all ponderable bodies to the precision of half a grain 
 in the weight of a hundred ounces ; that is to say, of a ten 
 thousandth part. It is employed, besides, for ascertaining the 
 specific gravity of solids, of liquids, and of air, by processes 
 extremely simple, and which do not require many subdivisions 
 in the weights. 
 
 We think the description above given will be sufficiently 
 
252 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 intelligible without a representation of this instrument. An 
 account of its application to the determination of specific grav- 
 ities will be found in vol. iii. of the Philosophical Magazine. 
 
 The Chinese Steelyard. 
 
 This instrument is used in China and the East Indies for 
 weighing gems, precious metals, &>c. The beam is a small 
 rod of ivory, about a foot in length. Upon this are three lines 
 of divisions, marked by fine silver studs, all beginning from 
 the end of the beam, whence the first is extended 8 inches, 
 the second 6, and the third 8. The first is European 
 weight, and the other two Chinese. At the other end of the 
 beam hangs a round scale, and at three several distances from 
 this end are holes, through which pass so many fine strings, 
 serving as different points of suspension. The first distance 
 makes If inches, the second 3, or double the former, and 
 the third 4, or triple the same. The instrument, when 
 used, is held by one of the strings, and a sealed weight of 
 about l oz. troy, is slid upon the beam until an equilibrium 
 is produced ; the weight of the body is then indicated by 
 the graduated scale above-mentioned. 
 
 The Danish Balance. 
 
 The Danish balance is a straight bar or lerer having a 
 heavy weight fixed to one end, and a hook or scale-pan to re- 
 ceive the substance, the weight of which is to be determined, 
 suspended from the other end. The fulcrum is movable, and 
 is made to slide upon the bar, till the beam rests in a horizon- 
 tal position, when the place of the fulcrum indicates the weight 
 required. In order to construct a balance of this kind, let 
 the distance of the centre of gravity from that point to which 
 the substance to be weighed is suspended be found by exper- 
 iment, when the beam is unloaded. Multiply this distance 
 by the weight of the whole apparatus, and divide the product 
 by the weight of the apparatus increased by the weight of the 
 body. This will give the distance from the point of suspen- 
 sion, at which the fulcrum being placed, the whole will be in 
 equilibrio : for example, supposing the distance of the centre 
 of gravity from the point of suspension to be 10 inches, and 
 the weight of the whole apparatus to be ten pounds ; sup- 
 pose, also, it were required to mark the divisions which 
 
CHAP. XXI. BENT LEVER BALANCE - BRADY'S BALANCE. 253 
 
 should indicate weights of one, two, or three pounds, &,c. 
 First, for the place of the division indicating one pound we 
 
 have = = 9 i*r inches > the P lace of the 
 
 marking one pound. For two pounds we have 
 inches, the place of the division indicating two pounds ; and 
 for three pounds 10 ? 3 = 7^ inches for the place of the divis- 
 ions indicating three pounds, and so on. 
 
 This balance is subject to the inconvenience of the divis- 
 ions becoming much shorter as the weight increases. The 
 distance between the divisions indicating one and two pounds 
 being, in the example we have given, about seven tenths of 
 an inch, whilst that between 20 and 21 pounds is only one 
 tenth of an inch ; consequently, a very small error in the 
 place of the divisions indicating the larger weights would 
 occasion very inaccurate results. The Danish balance is 
 represented ztjig. 194. 
 
 The Bent Lever Balance. 
 
 This instrument is represented at Jig. 195. The weight at 
 C is fixed at the end of the bent lever ABC, which is sup- 
 ported by its axis B on the pillar I H. A scale-pan E is sus- 
 pended from the other end of the lever at A. Through the 
 centre of motion B draw the horizontal line K B G, upon 
 which, from A and C, let fall the perpendiculars A K and C 
 D. Then, if B K and B D are reciprocally proportional to 
 the weights at A and C, they will be in equilibrio, but if not, 
 the weight C will move upwards or downwards along the arc 
 F G till that ratio is obtained. If the lever be so bent that 
 when A coincides with the line G K, C coincides with the 
 vertical B H, then as C moves from F to G, its momentum 
 will increase while that of the weight in the scale-pan E will 
 decrease. Hence the weight in E, corresponding to different 
 positions of the balance, may be expressed on the graduated 
 arc F G. 
 
 Brady 1 s Balance, or Weighing Apparatus. 
 
 This partakes of the properties both of the bent level 
 balance and of the steelyard. It is represented zijig. 196 
 A B C is a frame of cast iron having a great part of its weight 
 
 22 
 
254 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 towards A. F is a fulcrum, and E a movable suspender, 
 having a scale and hook at its lower extremity. E K G are 
 three distinct places, to which the suspender E may be appli- 
 ed, and to which belong respectively the three graduated 
 scales of division expressing weights, fG, c d, and a b. 
 When the scale and suspender are applied at G, the appara- 
 tus is in equilibrio, with the edge A B horizontal, and the 
 suspender cuts the zero on the scale a b. Now, any sub- 
 stance, the weight of which is to be ascertained, being put 
 into the scale, the whole apparatus turns about F, and the 
 part towards B descends till the equilibrium is again estab- 
 lished, when the weight of the body is read off from the scale 
 a b, which registers to ounces and extends to two pounds. 
 If the weight of the body exceed two pounds, and be less 
 than eleven pounds, the suspender is placed at K ; and when 
 the scale is empty, the number 2 is found to the right of the in- 
 dex of the suspender. If now weights exceeding two pounds 
 be placed in the scale, the whole again turns about F, and 
 the weight of the body is shown on the graduated arc c d, 
 which extends to eleven pounds, and registers to every two 
 ounces. 
 
 If the weight of the body exceed eleven pounds, the sus- 
 pender is hung on at E, and the weights are ascertained in 
 the same manner on the scale fC to thirty pounds, the sub- 
 divisions being on this scale quarters of pounds. The same 
 principles would obviously apply to weights greater or less 
 than the above. To prevent mistake, the three points of sup- 
 port G, K, E, are numbered 1, 2, 3; and the corresponding 
 arcs are respectively numbered in the same manner. When 
 the hook is used instead of the scale, the latter is turned up- 
 wards, there being a joint at m for that purpose. 
 
 The Weighing Machine for Turnpike Roads. 
 
 This machine is for the purpose of ascertaining the weight 
 of heavy bodies, such as wheel carriages. It consists of a 
 wooden platform placed over a pit made in the line of the road, 
 and which contains the machinery. The pit is walled within- 
 side, and the platform is fitted to the walls of the pit, but with- 
 out touching them, and it is therefore at liberty to move freely 
 up and down. The platform is supported by levers placed 
 beneath it, and is exactly level with the surface of the road, 
 so that a carriage is easily drawn on it, the wheels being upon 
 
CHAP. XXI. WEIGHING MACHINE. 255 
 
 the platform whilst the horses are upon the solid ground beyond 
 it. The construction of this machine will be readily under- 
 stood by reference to Jig. 197., in which the platform is sup- 
 posed to be transparent, so as to allow of the levers being 
 seen below it. 
 
 A, B, C, D, represent four levers tending towards the cen- 
 tre of the platform, and each movable on its fulcrum at A, B, 
 C, D ; the fulcrum of each rests upon a piece securely fixed 
 in the corner of the pit. The platform is supported upon the 
 cross pins a, 6, c, d, by means of pieces of iron which pro- 
 ject from it near its corners, and which are represented in the 
 plate by the short dark lines crossing the pins a, 6, c, d. The 
 four levers are connected under the centre of the platform, 
 but not so as to prevent their free motion, and are supported 
 by a long lever at the point F, the fulcrum of which rests upon 
 a piece of masonry at E : the end of this last lever passes be- 
 low the surface of the road into the turnpike house, and is 
 there attached to one arm of a balance, or, as in Salmon's 
 patent weighing machine, to a strap passing round a cylinder 
 which winds up a small weight round a spiral, and indicates, 
 by means of an index, the weight placed upon the platform. 
 
 Suppose the distance from A to F to be ten times as great 
 as that from A to a, then a force of one pound applied be- 
 neath F would balance ten pounds applied at a, or upon the 
 platform. Again : let the distance from E to G be also ten 
 times greater than the distance from the fulcrum E to F ; 
 then a force of one pound applied to raise up the end of the 
 lever G would counterpoise a weight often pounds placed up- 
 on F. Now, as we gain ten times the power by the first levers, 
 and ten times more by the lever E G, it follows, that a force of 
 one pound tending to elevate G, would balance 100 Ibs. placed 
 on the platform ; so that if the end of the lever G be attached 
 to one arm of a balance, a weight of 10 Ibs. placed in a scale 
 suspended from the other arm, will express the value of 1000 
 Ibs. placed upon the platform. The levers are counterpoised, 
 when the platform is not loaded,by a weight H applied to the end 
 of the last lever, continued beyond the fulcrum for that purpose. 
 
 Of Instruments for weighing by Means of a Spring. 
 
 The spring is well adapted to the construction of a weighing 
 machine, from the property it possesses of yielding in propor- 
 tion to the force impressed, and consequently giving a scale 
 
1256 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 of equal parts for equal additions of weight. It is liable, 
 however, to suffer injury, unless the steel of which it is com- 
 posed be very well tempered, from a want of perfect elasticity, 
 and, consequently, from not returning to its original place 
 after it has been forcibly compressed. This, however, must 
 be considered to arise, in a great measure, from imperfection 
 of workmanship, or of the material employed, or to its hav- 
 ing been subjected to too great a force. 
 
 The Spring Steelyard. 
 
 The little instrument known by this name is in very gen- 
 eral use, and is particularly convenient where great accuracy 
 is not necessary, as a spring, which will ascertain weights 
 from one pound to fifty, is contained in a cylinder only 4 
 inches long and inch diameter. 
 
 This instrument is represented at Jig. 198. It consists of 
 a tube of iron, of the dimensions just stated, closed at the 
 bottom, to which is attached an iron hook, for supporting the 
 substance to be weighed ; a rod of iron a b, four tenths of 
 an inch wide and one tenth thick, is firmly fixed in the cir- 
 cular plate c d, which slides smoothly in the iron tube.* 
 
 A strong steel spring is also fastened to this plate, and 
 passed round the rod a b without touching it, and without 
 coming in contact with the interior of the cylindrical tube. 
 The tube is closed at the top by a circular piece of iron 
 through which the piece a b passes. 
 
 Upon the face of a b the weight is expressed by divisions, 
 each of which indicates one pound, and five of such divisions 
 in the instrument now before us occupy two tenths of an inch. 
 The divisions, notwithstanding, are of sufficient size to ena- 
 ble them to be subdivided by the eye. 
 
 To use this instrument, the substance to be weighed is 
 suspended by the hook, the instrument being held by a ring 
 passing through the rod at the other end. The spring then 
 suffers a compression proportionate to the weight, and the 
 number of pounds is indicated by the division on the rod 
 which is cut by the top of the cylindrical tube. 
 
 Salter's improved Spring Balance. 
 
 A very neat form of the instrument last described has 
 been recently brought before the public by Mr. Salter, under 
 
CHAP. XXI. DYNAMOMETER. 257 
 
 the name of the Improved Spring Balance. It is represented 
 Aijig. 199. The spring is contained in the upper half of a 
 cylinder behind the brass plate forming the face of the in- 
 strument ; and the rod is fixed to the lower extremity of the 
 spring, which is consequently extended, instead of being com- 
 pressed, by the application of the weight. The divisions, 
 each indicating half a pound, are engraved upon the face of 
 the brass plate, and are pointed out by an index attached to 
 the rod. 
 
 Marriott's Patent Dial Weighing Machine. 
 
 The exterior of this instrument is represented vtjig. 200., 
 and the interior at Jig. 201. A B C is a shallow brass box, 
 having a solid piece as represented at A, to which the spring 
 D E F is firmly fixed by a nut at D. The other end of the 
 spring at F is pinned to the brass piece G H, to the part of 
 which at G is also fixed the iron racked plate I. A screw L 
 serves as a stop to keep this rack in its place. The teeth of 
 the rack fit into those of the pinion M, the axis of which 
 passes through the centre of the dial-plate, and carries ari 
 index which points out the weight. The brass piece G H is 
 merely a plate where it passes over the spring, and the tail 
 piece H, to which the weight is suspended, passes through 
 an opening in the side of the box. 
 
 Of the Dynamometer. 
 
 This is an important instrument in mechanics, calculated 
 to measure the muscular strength exerted by men and ani- 
 mals. It consists essentially of a spring steelyard, such as 
 that we first described. This is sometimes employed alone, 
 and sometimes in combination with various levers, which 
 allow of the spring being made more delicate, and conse- 
 quently increase the extent of the divisions indicating the 
 weight. 
 
 The first instrument of this kind appears to have been 
 invented by Mr. Graham, but it was too bulky and incon- 
 venient for use. M. le Roy made one of a more simple 
 construction. It consisted of a metal tube, about a foot long, 
 placed vertically upon a stand, and containing in the inside 
 a spiral spring, having above it a graduated rod terminating 
 in a globe. This rod entered the tube more or less in propor- 
 22* 
 
258 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 tion to the force applied to the globe, and the divisions 
 indicated the quantity of this force. Therefore, when a 
 man pressed upon the globe with all his strength, the divis- 
 ions upon the rod showed the number of pounds weight to 
 which it was equal. 
 
 An instrument of this kind for determining the force of a 
 blow struck by a man with his fist was lately exhibited at the 
 National Repository. It was fixed to a wall, from which it 
 projected horizontally. In place of the globe there was a 
 cushion to receive the blow, and as the suddenness with 
 which the spring returned rendered it impossible to read the 
 division upon the rod, another rod, similarly divided, was 
 forced in by the plate forming the basis of the cushion, and 
 remained stationary when the spring returned. The com- 
 mon spring steelyard, however, which we first described, is 
 in principle 'the same as M. le Roy's dynamometer, and is 
 much more conveniently constructed for the purpose we are 
 considering. The ring at one end may be fixed to an im- 
 movable object, and the hook at the other attached to a man, 
 or to an animal, and the extent to which the graduated rod 
 is drawn out of the cylinder shows at once the force which 
 is applied. Though this is perhaps the best, and certainly 
 the most simple dynamometer, others have been contrived, 
 which are, however, but modifications of the spring steelyard. 
 One of these is represented at fig. 202. The spiral spring 
 acts in the manner before described, but its divisions are in- 
 creased in size, and therefore rendered more perceptible by 
 means of a rack fixed to the plate, acting against the spiral 
 spring, the teeth of which move a pinion upon which the 
 arm I is fixed, pointing to the graduated arc K. 
 
 Another dynamometer has been invented by Mr. Salmon ; 
 it is represented atj^. 203., and is a combination of levers 
 with the spring. By means of these levers, a much more 
 delicate spring, and which is therefore more sensible, may be 
 employed than in the dynamometer last described. 
 
 The manner in which these levers and springs act will be 
 readily understood by an inspection of the figure. Like the 
 weighing machine for carriages, the fulcrum of each lever is 
 at one end, and the force is diminished, in passing to the 
 spring, in the ratio of the length of its arms. The spring 
 moves a pinion by means of a rack, upon which pinion a 
 hand is placed, indicating by divisions upon a circular dial- 
 plate the amount of the force employed. 
 
CHAP. XXI. COMPENSATION PENDULUMS. 259 
 
 The spring used in this machine is calculated to weigh 
 only about 50 Ibs. instead of about 5 cwt., as in the last de- 
 scribed ; but by means of the levers which intervene between 
 it and the force applied, it will serve to estimate a force equal 
 to 6 cwt, and might obviously be made to go to a much 
 greater extent, by varying the ratio of the length of the arms 
 of the levers. 
 
 ON COMPENSATION PENDULUMS. 
 
 (336.) It is said of Galileo, that, when very young, he ob- 
 served a lamp suspended from the roof of a church at Pisa, 
 swinging backwards and forwards with a pendulous motion. 
 This, if it had been remarked at all by an uneducated 
 mind, would, most probably, have been passed by as a com- 
 mon occurrence, unworthy of the slightest notice ; but to the 
 mind imbued with science no incident is insignificant ; and 
 a circumstance apparently the most trivial, when subjected 
 to the giant force of expanded intellect, may become of im- 
 mense importance to the improvement and to the well-being 
 of man. The fall of an apple, it is said, suggested to 
 Newton the theory of gravitation, and his powerful inind 
 speedily extended to all creation that great law which brings 
 an apple to the ground. The swinging of a lamp in a church 
 at Pisa, viewed by the piercing intellect of Galileo, gave rise 
 to an instrument which affords the most perfect measure of 
 time, which serves to determine the figure of the earth, and 
 which is inseparably connected with all the refinements of 
 modern astronomy. 
 
 The properties of the pendulum, and the manner in which 
 it serves to measure time, have been fully explained in Chap- 
 t3r XI. : and if a substance could be found not susceptible 
 of any change in its dimensions from a change of tempera- 
 ture, nothing more would be necessary, as the centre of 
 oscillation would always remain at the same distance from 
 the point of suspension. As every known substance, how- 
 ever, expands with heat, and contracts with cold, the length 
 of the pendulum will vary with every alteration of tempera- 
 ture, and thus the time of its vibration will suffer a corre- 
 sponding chancre. The effect of a difference of temperature 
 of 25, or that which usually occurs between winter and 
 summer, would occasion a clock furnished with a pendulum 
 having an iron rod to gain or lose six seconds in twenty-four 
 hours. 
 
260 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 It became, then, highly important to discover some means 
 of counteracting this variation to which the length of the 
 pendulum was liable, or, in other words, to devise a method 
 by which the centre of oscillation should, under every change 
 of temperature, remain at the same distance from the point 
 of suspension : happily, the difference in the rate of expansion 
 of different metals presented a ready means of effecting this. 
 
 Graham, in the year 1715, made several experiments to 
 ascertain the relative expansions of various metals, with a 
 view of availing himself of the difference of the expansions 
 of two or more of them when opposed to each other, to con- 
 struct a compensating pendulum. But the difference he 
 found was so small, that he gave up all hope of being able to 
 accomplish his object in that way. Knowing, however, that 
 mercury was much more affected by a given change of tem- 
 perature than any other substance, he saw that if the mercu- 
 ry could be made to ascend while the rod of the pendulum 
 became longer, and vice, vcrzti, the centre of oscillation might 
 always be kept at the same distance from the. point of sus- 
 pension. This idea happily gave birth to the mercurial 
 pendulum, which is now in very general use. 
 
 In the mean time, Graham's suggestion excited the inge- 
 nuity of Harrison, originally a carpenter at Barton in Lin- 
 colnshire, who, in 1720, produced a pendulum formed of 
 parallel brass and steel rods, known by the name of the 
 gridiron pendulum. 
 
 In. the mercurial pendulum, the bob or weight is the mate- 
 rial affording the compensation ; but in the gridiron pendu- 
 lum, the object is attained by the greater expansion of the 
 brass rods, which raise the bob upwards towards the point of 
 suspension as much as the steel rods elongate downwards. 
 
 In the present article, we shall describe such compensation 
 pendulums as appear to us likely to answer best in practice ; 
 and we trust we shall be able to simplify the subject so as to 
 render a knowledge of mathematics in the construction of 
 this important instrument unnecessary. 
 
 The following table contains the linear expansion of vari- 
 ous substances in parts of their length, occasioned by a 
 change of temperature amounting to one degree. We have 
 taken the liberty of extracting it from a very valuable paper 
 by F. Bailey, Esq., on the mercurial compensation pendulum, 
 published in the Memoirs of the Astronomical Society of 
 London for 1824. 
 
CHAP. XXI. 
 
 COMPENSATION PENDULUMS. 
 
 261 
 
 TABLE I. 
 
 Linear Expansion of Various Substances for one Degree of 
 Fahrenheit's Thermometer. 
 
 Substances. 
 
 
 Expansions. 
 
 Authors. 
 
 White Deal, .... 
 English Flint Glass, 
 Iron (cast), 
 
 i 
 j 
 
 0000022685 
 0000028444 
 0000047887 
 0000061700 
 
 Captain Kater. 
 Dr. Struve. 
 Dulong and Petit. 
 General Roy. 
 
 Iron (wire), . . . . . 
 
 1 
 
 0000065668 
 0000068613 
 
 Dulong and Petit. 
 Lavoisier and L. 
 
 
 
 0000069844 
 
 Hasslar. 
 
 Steel (rod), 
 
 
 0000063596 
 
 General Roy. 
 
 Brass, . 
 
 
 .0000104400 
 
 C Commiss. of Weights 
 < and Measures mean 
 
 
 
 0000159259 
 
 <J of several experiments. 
 Smeatofu 
 
 
 
 0000163426 
 
 Ditto. 
 
 Zinc (hammered), . 
 Mercury in bulk, . . 
 
 
 0000172685 
 00010010 
 
 Ditto. 
 Dulong and Petit. 
 
 From this table it is easy to determine the length of a rod 
 of any substance, the expansion of which shall be equal to 
 that of a rod of given length, of any other substance. 
 
 The lengths of such rods will be inversely proportionate to 
 their expansions. If, therefore, we divide the lesser expan- 
 sion by the greater (supposing the rod the length of which is 
 given to be made of the lesser expansible material), and mul- 
 tiply the given length by this quotient, we shall have the 
 required length of a rod, the expansion of which will be 
 equal to that of the rod given. For example : The ex- 
 pansion of a rod of steel being, from the above table, 
 0000063596, and that of brass, -0000104400; if it were 
 required to determine the length of a rod of brass which 
 should expand as much as a rod of steel of 39 inches in 
 
 length, we have . OOU0104 ^ = '6091, which, multiplied by 39, 
 gives 23-75 inches for the length of brass required. 
 
 We shall here, in order to facilitate calculation, give the 
 
262 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 ratio of the lengths of such substances as may be employed 
 in the construction of compensation pendulums. 
 
 TABLE II. 
 
 Steel rod and brass compensation, as 1, 
 
 Iron wire rod and lead compensation, -4308 
 
 Steel rod and lead compensation, '3993 
 
 Iron wire rod and zinc compensation, '3973 
 
 Steel rod and zinc compensation, *3682 
 
 Glass rod and lead compensation, *3007 
 
 Glass rod and zinc compensation, -2773 
 
 Deal rod and lead compensation, -1427 
 
 Deal rod and zinc compensation, -1313 
 
 Steel rod and mercury in a steel cylinder, -0728 
 
 Steel rod and mercury in a glass cylinder, -0703 
 
 Glass rod and mercury in a glass cylinder, '0529 
 
 It is evident that in this table the decimals express the 
 length of a roc! of the compensating material, the expansion 
 of which is equal to that of a pendulum rod whose length is 
 unity. 
 
 As we are not aware of the existence of any work which 
 contains instructions that might enable an artist or an ama- 
 teur to make a compensation pendulum, we shall endeavor to 
 give such detailed information as may free the subject from 
 every difficulty. 
 
 The pendulum of a clock is generally suspended by a 
 spring, fixed to its upper extremity, and passing through a 
 slit made in a piece which is called the cock of the pendu- 
 lum. The point of suspension is, therefore, that part of the 
 spring which meets the lower surface of the cock. Now the 
 istance of the centre of oscillation of the pendulum from 
 his point may be varied in two ways ; the one by drawing 
 up the spring through this slit, and the other by raising the 
 bob of the pendulum. Either of these methods may be 
 practised in the compensation pendulum, but the former is 
 subject to objections from which the latter is exempt. 
 
 Suppose it were required to compensate a pendulum of 39 
 inches in length, of steel, by means of the expansion of a 
 brass rod. Here, referring to -Jf.g. 204., we have S C 39 
 inches (which is to remain constant) of steel ; the pendulum 
 
CHAP. XXI. COMPENSATION PENDULUMS. 263 
 
 spring, passing through the cock at S, is attached to another 
 rod of steel, which is fixed to the cross piece R A at A. 
 The other end of the cross piece at R is fastened to a brass 
 rod, the lower extremity of which is fixed to the cock of the 
 pendulum at B. Now the brass rod B R must expand up- 
 wards, as much as the steel rod A C expands downwards ; 
 and the length of the brass must be such as to effect this, 
 leaving 39 inches of the steel rod below the cock of the pen- 
 dulum. 
 
 Let us first try 80 inches of steel. Multiplying this by 
 6091, we have 48*73 inches for the length of brass, which 
 compensates 80 inches of steel. But as 48-73 inches of the 
 steel, equal in length to the brass, would in this case be 
 above the cock of the pendulum, it would leave only 31-27 
 inches below it, instead of 39 inches. 
 
 Let us now try 100 inches of steel. This, multiplied as 
 before by -6091, gives 60-91 inches, according to the expan- 
 sions which we have used, for the length of the brass rod, 
 and leaves 39-09 inches below the cock of the pendulum, 
 which is sufficiently near for our present purpose. 
 
 From what has been said, we may perceive that the total 
 length of the material of which the pendulum rod is com- 
 posed must be always equal to the length of the pendulum 
 added to the length of the compensation. 
 
 In this instance we have effected our object, by drawing 
 the pendulum-spring through the slit ; but we will now show 
 how the same thing may be done by moving the bob of the 
 pendulum. At Jig. 205., let S C, as before, be equal to 39 
 inches. Let the steel rod S D turn off at right angles at D, 
 and let a rod of brass B R, of 61 inches in length, ascend 
 perpendicularly from this cross piece to R. To the upper 
 part of the brass rod fix another cross piece R A, and from 
 the extremity A let a steel rod descend to E, bending it as in 
 the figure till it reaches C. Now the total length of the 
 pieces of steel expanding downwards is equal to S D, D F, 
 and F C (amounting together to 39 inches), to which must 
 be added a length of steel equal to that of the brass rod B R, 
 (61 inches), making together 100 inches of steel, as before, 
 the expansion of which downwards is compensated by that 
 of the brass rod, of 61 inches in length, expanding upwards. 
 
 This form, however, is evidently inconvenient, from the 
 great length of brass and steel which is carried above the 
 cock of the pendulum ; but it is the same thing whether the 
 
204 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 brass and steel be each in one piece, or divided into several, 
 provided the pieces of steel be all so arranged as to expand 
 downwards, and those of brass upwards. Thus, ztjig. 206., 
 the portions of steel expanding downwards are together equal, 
 as before, to 100 inches, and the two brass pieces expanding 
 upwards are together equal to 61 inches ; so that, in fact, 
 the two last forms of compensation which we have described 
 differ in no respect from each other in principle, but only in 
 the arrangement of the materials. The last is the half of 
 the gridiron pendulum, the remaining bars being merely du- 
 plicates of those we have described, and serving no other 
 purpose but to form a secure frame- work. 
 
 Harrison's Gridiron Pendulum. 
 
 After what has been said, little more is necessary than to 
 give a representation of this pendulum. This is done at 
 jig. 207., in which the darker lines represent the steel rods, 
 and the lighter those of brass. The central rod is fixed at 
 its lower extremity to the middle of the third cross piece from 
 the bottom, and passes freely through holes in the cross 
 pieces which are above, whilst the other rods are secured 
 near their extremities to the cross pieces by pins passing 
 through them. In order to render the whole more secure, 
 the bars pass freely through holes made in two other cross 
 pieces, the extremities of which are fixed to the exterior steel 
 wires. As different kinds of the same metal vary in their 
 rate of expansion, the pendulum when finished may be found 
 upon trial to be not duly compensated. In this case, one or 
 more of the cross pieces is shifted higher or lower upon the 
 bars, and secured by pins passed through fresh holes. 
 
 Troughton's Tubular Pendulum. 
 
 This is an admirable modification of Harrison's gridiron 
 pendulum. It is represented atj^ 1 . 208., where it may be 
 seen that it has the appearance of a simple pendulum, as the 
 whole compensation is concealed within a tube six tenths of 
 an inch in diameter. 
 
 A steel wire, about one tenth of an inch in diameter, is 
 fixed in the usual manner to the sprihg by which the pendu- 
 lum is suspended. This wire passes to the bottom of an 
 interior brass tube, in the centre of which it is firmly screwed 
 

 CHAP. xxi. TROUGH-TON'S TUBULAR PENDULUM. 265 
 
 The top of this tube is closed, the steel rod passing freely 
 through a hole in the centre. Into the top of this interior 
 tube two steel wires, of one tenth of an inch in diameter, are 
 screwed into holes made in that diameter, which is at right 
 angles to the motion of the pendulum. These wires pass 
 down the tabe without touching either it or the central rod, 
 through holes made in the piece which closes the bottom of 
 the interior tube. The lower extremities of these wires, 
 which project a little beyond the inner tube, are securely 
 fixed in a piece which closes the bottom of an exterior brass 
 tube, which is of such a diameter as just to allow. the interior 
 tube to pass freely through it, and of a sufficient length to 
 extend a little above it. The top of the exterior tube is 
 closed like that of the interior, having also a hole in its cen- 
 tre, to allow the first steel rod to pass freely through it. Into 
 the top of the exterior tube, in that diameter which coincides 
 with the motion of the pendulum, a second pair of steel wires 
 of the same diameter as the former are screwed, their dis- 
 tance from the central rod being equal to the distance of 
 each from the first pair. They consequently pass down with- 
 in the interior tube, and through holes made in the pieces 
 closing the lower ends of both the interior and exterior tubes. 
 The lower ends of these wires are fastened to a short cylin- 
 drical piece of brass of the same diameter as the exterior 
 tube, to which the bob is suspended by its centre. 
 
 Fig, 209. is a full sized section of the rod ; the three con- 
 centric circles represent the two tubes, and the rectangular 
 position of the two pair of wires round the middle one is 
 shown by the five small circles. 
 
 Fig. 210, is the part which closes the upper end of the 
 interior tube. The two small circles are the two wires which 
 proceed from it, and the three large circles show the holes 
 through which the middle wire and the other pair of wires 
 pass. 
 
 Fig. 211. is the bottom of the interior tube. The small 
 circle in the centre is where the central rod is fastened to it, 
 the others the holes for the other four wires to pass through. 
 
 Fig, 212. is the part which closes the top of the external 
 tube. In the large circle in the centre a small brass tube is 
 fixed, which serves as a covering for the upper part of the 
 middle wire, and the two small circles are to receive the 
 wires of the last expansion. 
 
 Fig, 213. represents the bottom of the exterior tube, in 
 23 
 
266 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 which the small circles show the places where the wires of 
 the second expansion are fastened, and the larger ones the 
 holes for the other pair of wires to pass through. 
 
 Fig. 214. is a cylindrical piece of brass, showing the man- 
 ner in which the lower ends of the wires of the last expan- 
 sion are fastened to it, and the hole in the middle is that by 
 which it is pinned to the centre of the bob. The upper ends 
 of the two pair of wires are, as we have observed, fastened 
 by screwing them into the pieces which stop up the ends of 
 the tubes, but at the lower ends they are all lixed as repre- 
 sented in jig. 214. The pieces represented by Jigs. 213. and 
 214. have each a jointed motion, by means of which the fel- 
 low wires of each pair would be equally stretched, although 
 they were not exactly of the same length. 
 
 The action of this pendulum is evidently the same as that 
 of the gridiron pendulum, as we have three lengths of steel 
 expanding downwards, and two of brass expanding upwards. 
 The weight of the pendulum has a tendency to straighten 
 the steel rods, and the tubular form of the brass compensa- 
 tion effectually precludes the fear of its bending ; an advan- 
 tage not possessed by the gridiron pendulum, in which brass 
 rods are employed. 
 
 Mr. Troughton, to the account he has given of this pen- 
 dulum in Nicholson's Journal, for December, 1804, has 
 added the lengths of the different parts of which it was^com- 
 posed, and the expansions of brass and steel from which these 
 lengths were computed. The length of the interior tube 
 was 31*9 inches, and that of the exterior one 32*8 inches, to 
 which must be added 0-4, the quantity by which in this pen- 
 dulum the centre of oscillation is higher than the centre of 
 the bob. These are all of brass. The parts which are of 
 steel are, the middle wire, which, including 0'6, the length 
 of the suspension spring, is 39-3 inches ; the first pair of 
 wires 32-5 inches ; and the second pair, 33-2 inches. The 
 expansions used were for brass '00001666, and for steel 
 00000661 , in parts of their length for one degree of temper- 
 ature. 
 
 Benzcnberg's Pendulum. 
 
 This pendulum is mentioned in Nicholson's Journal, for 
 April, 1804, and is taken from Voigt's Magazin fur den Neu- 
 esten Zustande der Naturkunde, vol. iv. p. 787. The com- 
 pensation appears to have been effected by a single rod of 
 
CHAP. xxi. BENZENKERG'S PENDULUM. 207 
 
 lead in the centre, of about half an inch thick ; the descend- 
 ing rods were made of the best thick iron wire. 
 
 As this pendulum deserves attention from the ease with 
 which it may be made, and as others which have since been 
 produced resemble it in principle, we have given a represen- 
 tation of it vA.ji>g> 215., where A B C D are two rods of iron 
 wire riveted into the cross pieces A C B D. E F is a rod 
 of lead pinned to the middle of the piece B D, and also at 
 its upper extremity to the cross piece G H, into which the 
 second pair of iron wires are fixed, which pass downwards 
 freely through holes made in the cross piece B D. The 
 lower extremities of these last iron wires are fastened into 
 the piece K L, which carries the bob of the pendulum. 
 
 To determine the length of lead necessary for the compen- 
 sation, we must recollect, as before, that the distance from 
 the point of suspension to the centre of the bob (speaking 
 always of a pendulum intended to vibrate seconds) must be 
 39 inches. Lfet us suppose the total length of the iron wire 
 to be 60 inches; then, from the table which we have given, 
 we have -4308 -for the length of a rod of lead, the expansion 
 of which is equivalent to that of an iron rod whose length is 
 unity. Multiplying 60 inches by -4308, we have 25*84 inches 
 of lead, which would compensate 60 inches of iron; but 
 this, taken from 60 inches, leaves only 34-16 instead of 39 
 inches. Trying again, in like manner, 68*5 inches of iron, 
 we find 29-5 inches of lead for the length, affording an equiv- 
 alent compensation, and which, taken from 68*5 inches, 
 leaves 39 inches. 
 
 The length of the rod of lead then required as a compen- 
 sation in this" pendulum is about 29 inches. 
 
 The writer of this article would suggest another form for 
 this pendulum, which has the advantage of greater simplici- 
 ty of construction. 
 
 S A, fig. 216, is a rod of iron wire, to which the pendulum 
 spring is attached. Upon this passes a cylindrical tube of 
 lead, 294- inches long, which is either pinned at its lower ex- 
 treniity to the end of the iron Tod S A, or rests upon a nut 
 firmly screwed upon the extremity of this rod. 
 
 A tube of sheet iron passes over the tube of lead, and is 
 furnished at top with a ftanche, by which it is supported upon 
 the leaden tube ; or it may be fastened to the top of this tube 
 in any manner that may' be thought convenient. 
 
 Tne bob of the pendulum may be either passed upon the 
 
268 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 iron tube (continued to a sufficient length) and secured by a 
 pin passing through the centre of the bob, or the iron tube 
 may be terminated by an iron wire serving the same purpose. 
 Here we have evidently the same expansions upwards and 
 downwards as in the gridiron form, given to this pendulum 
 by Mr. Benzenberg, joined to the compactness of Troughton's 
 tubular pendulum. 
 
 Ward's Compensation Pendulum. 
 
 In the year 1806, Mr. Henry Ward, of Blandford in Dor- 
 setshire, received the silver medal of the Society of Arts for 
 the compensation pendulum which we are about to describe. 
 
 Fig. 217. is a side view of the pendulum rod when togeth- 
 er. H H and I I are two flat rods of iron about an eighth 
 of an inch thick. K K is a bar of zinc placed between 
 them, and is nearly a quarter of an inch thick. The corners 
 of the iron bars are bevelled off, which gives them a much 
 lighter appearance. These bars are kept together by means 
 of three screws, O O O, which pass through oblong holes in 
 the bars H H and K K, and screw into the rod I I. The 
 bar H H is fastened to the bar of zinc K K, by the screw m, 
 which is called the adjusting screw. This screw is tapped 
 into H H, and passes just through K K ; but that part of the 
 screw which passes K K has its threads turned off. The 
 iron bar I I has a shoulder at its upper end, and rests on the 
 top of the zinc bar K K, and is wholly supported by it. 
 There are several holes for the screw w, in order to adjust 
 the compensation. 
 
 The action of this pendulum is similar to that last de- 
 scribed, the zinc expanding upwards as much as the iron 
 rods expand downwards, and consequently the distance 
 from the point of suspension to the centre of oscillation 
 remains the same. 
 
 Mr. Ward states that the expansion of the zinc he used 
 (hammered zinc) was greater than that given in the tables. 
 He found that the true length of the zinc bar should be 
 about 23 inches : our computation would make it nearly 26. 
 
 The Compensation Tube of Julien le Roy. 
 
 We mention this merely to state that it is similar in prin- 
 ciple to the apparatus represented at fig. 204., with merely 
 

 CHAP. xxi. RATER'S PENDULUM. 209 
 
 this difference, that, instead of the steel rod being fixed to 
 a cross piece proceeding from the brass bar B R, it is at- 
 tached to a cap fitted upon a brass tube (through which it 
 passes) of the same length as that of the brass rod B R. 
 Cassini spoke well of this pendulum, and it was used in the 
 observatory of Cluny about the year 1748. 
 
 Deparcieutfs Compensation. 
 
 This was contrived in the same year as that invented by 
 Jnlien le Roy. It is represented atj%-. 218, where A B D F 
 is a steel bar, the ends of which are to be fixed to the lower 
 sides of pieces forming a part of the cock of the pendulum. 
 G E I H is of brass, and stands with its extremities resting 
 on the horizontal part B D of the steel frame. The upper 
 part E I of the brass frame passes above the cock of the pen- 
 dulum, and admits the tapped wire K, to which the pendulum 
 spring is fixed through a squared hole in the middle. A nut 
 upon this tapped wire gives the adjustment for time. The 
 spring passes through the slit in the cock in the usual 
 manner. 
 
 It may be easily perceived that this pendulum is 'in 1 princi- 
 ple the same as that of Le Roy ; the expansion of the total 
 length of steel A B S C downwards being compensated by 
 the equivalent expansion of the brass bar G E upwards. It 
 is, however, preferable to Le Roy's, because the compensa- 
 tion is contained in the clock case. 
 
 Deparcieux had previously published, in the year 1739, an 
 improvement of an imperfectly compensating '''pendulum, 
 proposed in the year 1733 by Regnauld, a clockmaker of 
 Chalons. In this pendulum Deparcieux employed a lever 
 with unequal arms to increase the effect of the expansion of 
 the brass rod , which was too short. 
 
 We may here remark, that all fixed compensations are 
 liable to the same objection, namely, that of not moving with 
 the pendulum, and therefore not taking precisely the same 
 temperature. 
 
 Captain 'Kdter's Compensation iFVndulum. 
 
 In Nicholson's Journal, for July, 1808, is the description 
 of a compensation pendulum by the writer of this article. 
 In this pendulum the rod is of white deal, three quarters of 
 23 * ha !,-. '.::-.;: 
 
 
270 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 an inch wide, and a quarter of an inch thick. It was placed 
 in an oven, and suffered to remain there for a long time until 
 it became a little charred. The ends were then soaked in 
 melted sealing-wax; and the rod, being cleaned, was coated 
 several times with copal varnish. To the lower extremity of 
 the rod a cap of brass was firmly fixed, from which a strong 
 steel screw proceeded for the purpose of regulating the pen- 
 dulum for time in the usual manner. 
 
 A square tube of zinc was cast, seven inches long, and 
 three quarters of an inch square ; the internal dimensions 
 being four tenths of an inch. The lower part of the pendu- 
 lum rod was cut away on the two sides, so as to slide with 
 perfect freedom within the tube of zinc. To the bottom 
 of this zinc tube a piece of brass a quarter of an inch thick 
 was soldered, in which a circular hole was made nearly four 
 tenths of an inch in diameter, having a screw on the inside. 
 A cylinder of zinc, furnished with a corresponding screw on 
 its surface, fitted into this aperture, and a thin plate of brass 
 screwed upon the cylinder, served as a clamp to prevent any 
 shake after the length of zinc necessary for compensation 
 should have been determined. A hole was made through the 
 axis of the cylinder, through which passed the steel screw 
 terminating the pendulum rod. 
 
 An opening was made through the bob of the pendulum, 
 extending to its centre, to admit the square tube of zinc 
 which was fixed at its upper extremity to the centre of the 
 bob. The pendulum rod passed through the bob in the usual 
 manner, and the whole was supported by a nut on the steel 
 screw at the extremity. 
 
 In this form, the compensation acts immediately upon the 
 centre of the bob, elevating it along the rod as much as the 
 rod elongates downwards : the method of calculating the 
 length of the required compensation is precisely the same as 
 that we have before given. 
 
 Assuming the length of the deal rod to be 43 inches, and 
 multiplying this by -1313 from Table II., we have 5-64 inches 
 for the length of the zinc necessary to counteract the expan- 
 sion of the deal. The length of the steel screw, between the 
 termination of the pendulum rod and the nut, was two inches, 
 and that of the suspension spring one inch. Now, 3 inches of 
 steel multiplied by -3682 wouJd give 1-10 inch for the length 
 of zinc which would compensate the steel, and, adding this 
 to 5-64 inches, we have 6-74 inches fi>r the whole length of 
 zinc required. 
 
CHAP. xxi. REID'S PENDULUM. 271 
 
 In this pendulum, the length of the compensating part may 
 be varied by means of the zinc cylinder furnished with a 
 screw for that purpose. The bob of this pendulum and its 
 compensation are represented at Jig. 219. 
 
 It has been objected to the use of wooden pendulum rods, 
 that it is difficult, if not impossible, to secure them from the 
 action of moisture, which would at once be fatal to their cor- 
 rect performance. The pendulum now before us has, how- 
 ever, been going with but little intermission since it was first 
 constructed : it is attached to a sidereal clock, not of a supe- 
 rior description, and exposed to very considerable variations 
 of moisture and dryness ; yet the change in its rate has been 
 so very trifling as to authorize the belief, that moisture has lit- 
 tle or no effect upon a wooden rod prepared in the manner 
 we have described. Its rate, under different temperatures, 
 tliows that it is over-compensated; the length of the zinc 
 remaining, as stated in Nicholson's Journal, 7-42 inches, 
 instead of which it appears, by our present compensation, 
 that it should be 6-78 inches. 
 
 Reid's Condensation Pendulum, 
 
 Mr. Adam Heid of Woolwich presented to the Society of 
 Arts, in 1809, a compensation pendulum, for which he was 
 rewarded with fifteen guineas. This pendulum is the same 
 in principle with that last described ; the rod, however, is of 
 steel instead of wood, and the compensation possesses no 
 means of adjustment. This pendulum is represented at Jig. 
 220., where S B is the steel rod, a little thicker where it en- 
 ters the bob C, and of a lozenge shape to prevent the bob 
 turning, but above and below it is cylindrical. 
 
 A tube of zinc D passes to the centre of the bob from 
 below, and the bob is supported upon it by a piece which 
 crosses its centre, and which meets the upper end of the tube. 
 
 The rod being passed through the bob and zinc tube, a nut 
 is applied upon a screw at the lower extremity of the rod in 
 the usual manner. If the compensation should be too much, 
 the zinc tube is to be shortened until it is correct. 
 
 The length of the zinc tube will be the same in this pen- 
 dulum as in that of Mr. Ward about 23 inches, if his ex- 
 periments are to be relied upon. 
 
 The objection to this pendulum appears to be its great 
 lengtri, which amounts to 62 inches. We conceive it would 
 
272 THE ELEMENTS OF MECHANICS. CHAP. XXI 
 
 be preferable to place the zinc above the bob, as in the modi- 
 fication which we have suggested of Benzenberg's pendulum. 
 
 Elticott's Pendulum. 
 
 It appears that the idea of combining the expansions of 
 different metals with a lever, so as to form a compensation 
 pendulum, originated with Mr. Graham : for Mr. Short, in 
 the Philosophical Transactions for 1752, states that he was 
 informed by Mr. Shelton, that Mr. Graham, in the year 1737, 
 made a pendulum, consisting of three bars, one of steel be- 
 tween two of brass ; and that the steel bar acted upon a lever 
 so as to raise the pendulum when lengthened by heat, and to 
 let it down when shortened by cold. 
 
 This pendulum, however, was found upon trial to move by 
 jerks, and was therefore laid aside by the inventor to mak 
 way for the mercurial pendulum. 
 
 Mr. Short also says, that Mr. Fotheringham, a Quaker c/ 
 Lincolnshire, caused a pendulum to be made, in the year 
 1738 or 1739, consisting of two bars, one of brass and the 
 other of steel, fastened together by screws, with levers to raise 
 or let down the bob, and that these levers were placed above 
 the bob. 
 
 Mr. John Ellicott of London had made very accurate ex- 
 periments on the relative expansions of seven different metals, 
 which, however, will be found to differ more or less from the 
 results of the experiments of others. It is not, however, from 
 this to be concluded that EHicott's determinations were erro- 
 neous ; for the expansion of 'a metal will suffer considerable 
 change even by the processes to which it ! is necessarily sub- 
 jected jn the construction of a pendulum. It is therefore 
 desirable, whenever a' compensation pendulum is to 'be- made, 
 that the expansions of the materials, employed should be 
 determined after the processes of drilling; filing and ham- 
 mering have been gone through. 
 
 It has bejen objected to Harrison's gridiron pendulum, that 
 the adjustment of the rods was inconvenient, and that the 
 expansion of the bob supported at its lower edge would un- 
 less taken into the account, vitiate the compensation. These 
 considerations, it is supposed, gave risfe to Elh'cott's pendu- 
 lum, which is nearly similar to those we 'have just mentioned. 
 
 EHicott's pendulum is thus.' constructed :- A bar of brass 
 and a bar of iron are firmly fixed together at their upper ends, 
 
CHAP. XXi. COMPENSATION PENDULUM. 273 
 
 the bar of brass lying upon the bar of iron, which is the rod 
 of the pendulum. These bars are held near each other by 
 screws passing through oblong holes in the brass, and tapped 
 into the iron, and thus the brass is allowed to expand or con- 
 tract freely upon the iron with any change of temperature. 
 The brass bar passes to the centre of the bob of the pendu- 
 lum, a little above and below which the iron is left broader 
 for the purpose of attaching the levers to it, and the iron is 
 made of a sufficient length to pass quite through the bob 
 of the pendulum. 
 
 The pivots of two strong steel levers turn in two holes 
 drilled in the broad part of the iron bar. The short arms of 
 these levers are in contact with the lower extremity of the 
 brass bar, and their longer arms support the bob of the pendu- 
 lum by meeting the heads of two screws which pass horizon- 
 tally from each side of the bob towards its centre. By ad- 
 vancing these screws towards the centre of the bob, the 
 longer arms of the lever are shortened, and thus the compen- 
 sation may be readily adjusted. At the lower end of the iron 
 rod, under the bob, a strong double spring is fixed, to support 
 the greater part of the weight of the bob by its pressure up- 
 wards against two points at equal distances from the pendu- 
 lum rod. Mr. Ellicott gave a description of this pendulum 
 to the Royal Society in 1752, but he says the thought was 
 executed in 1738. As this pendulum is very seldom met 
 with, we think it unnecessary to give a representation of it. 
 
 Compensation by Means of a Compound Bar of Steel and 
 Brass. 
 
 Several compensations for pendulums have been proposed, 
 by means of a compound bar formed of steel and brass sol- 
 dered together. In a bar of this description, the brass expand- 
 ing more than the steel, the bar becomes curved by a change 
 of temperature, the brass side becoming convex and the steel 
 concave with heat. Now, if a bar of this description have its 
 ends resting on supports on each side the cock of the pen- 
 dulum, the bar passing above the cock with the brass upper- 
 most, if the pendulum spring be attached to the middle of the 
 bar, and it pass in the usual manner through the slit of the 
 cock, it is evident that, by an increase of temperature, the 
 bar will become curved upwards, and the pendulum spring 
 be drawn upwards through the slit, and thus the elongation 
 
274 THE ELEMENTS OF MECHANICS. CHAP. XXI 
 
 of the pendulum downwards wiU be compensated. The 
 compensation may be adjusted by varying the distance of the 
 points of support from the middle of the bar. 
 
 Such was one of the modes of compensation proposed by 
 Nicholson. Others of the same description (that is, with 
 compound bars) have been brought before the public by Mr. 
 Thomas Doughty and Mr. David Ritchie; but as they are 
 supposed to be liable to many practical objections, we do not 
 think it requisite to describe them more particularly. 
 
 There is, however, a mode of compensation by means of a 
 compound bar, described by M. Biot in the first volume of his 
 Traite de Physique, which appears to possess considerable 
 merit, of which he mentions having first witnessed the suc- 
 cessful employment by the inventor, a clockmaker named 
 Martin. At Jig, 2l., S C is the rod of the pendulum, made 
 in the usual manner, of iron or steel ; this rod passes through 
 the middle of a compound bar of brass and steel (the brass 
 being undermost), which should be furnished with a short tube 
 and screws, by means of which, or by passing a pin through 
 the tube and rod, it may be securely fixed at any part of the 
 pendulum rod. 
 
 Two small equal weights W W slide along the compound 
 bar, and, when their proper position has been determined, 
 may be securely clamped. ',""J^. 
 
 The manner in which this compensation acts is thus : Sup- 
 pose the temperature to increase, the brass expanding more 
 than the steel, the bar becomes curved, and its extremities 
 carrying the weights W and W are elevated, and thus the 
 place of the centre of oscillation is made to approach the 
 point of suspension as much, when the compensation is prop- 
 erly adjusted, as it had receded from it by the elongation 
 of the pendulum rod. 
 
 There are three methods of adjusting this compensation : 
 the first, by increasing or diminishing the weights W and W ; 
 the second, by varying the distance of the weights W and 
 W from the middle of the bar; and the third, by varying the 
 distance of the bar from the bob of the pendulum, taking 
 care not to pass the middle of the rod. The effect of the 
 compensation is greater as the weights W and W are greater 
 or more distant from the centre of the bar, and also as the 
 bar is nearer to the bob, of the pendulum. 
 
 M. Biot says that he and M. Matthieu employed a pendu- 
 um of this kind for a long time in making astronomical ob 
 
CHAP. XXI. MERCURIAL PENDULUM. 275 
 
 servations, in which they were desirous of attaining an ex- 
 treme degree of precision, and that they found its rate to be 
 always perfectly regular. 
 
 In all the pendulums which we have described, the bob is 
 supposed to be fixed to the rod by a pin passing through its 
 centre, and the adjustment for time is to be made by means 
 of a small weight sliding upon the rod. 
 
 Of the Mercurial Pendulum. 
 
 We have been guided, in our arrangement of the pendu- 
 lums which we have described, by the similarity in the mode 
 of compensation employed ; and we have now to treat of 
 that method of compensation which is effected by the expan- 
 sion of the material of which the bob itself of the pendulum 
 is composed. 
 
 On this subject, as we have before observed, an admirable 
 paper, from the pen of Mr. Francis Baily, may be found in 
 the Memoirs of the Astronomical Society of London, which 
 leaves nothing to be desired by the mathematical reader. But 
 as our object is to simplify, and to render our subjects as 
 popular as may be, we must endeavor to substitute for the 
 perfect accuracy which Mr. Baily's paper presents, such rules 
 as may be found not only readily intelligible, but practically 
 applicable, within the limits of those inevitable errors which 
 arise from a want of knowledge of the exact expansion of the 
 materials employed. 
 
 At Jig. 22*2., let S B represent the rod of a pendulum, and 
 F C B a metallic tube or cylinder, supported by a nut at the 
 extremity of the pendulum rod, in the usual manner, and 
 having a greater expansibility than that of the rod. Now 
 C, the centre of gravity, supposing the rod to be without 
 weight, will be in the middle of the cylinder ; and if C B, or 
 half the cylinder, be of such a length as to expand upwards 
 as much as the pendulum rod S B expands downwards, it is 
 evident that the centre of gravity C will remain, under any 
 change of temperature, at the same distance from the point 
 of suspension S. M. Biot imagined that, in effecting this, a 
 compensation sufficiently accurate would be obtained ; but 
 Mr. Baily has shown that this is by no means the fact. 
 
 Let us suppose the place of the centre of oscillation to 
 be at O, about three or four tenths of an inch, in a pendu- 
 lum of the usual construction, below the centre of gravity. 
 
276 THE ELEMENTS OP MECHANICS. CHAP. XXI 
 
 Now, the object of the compensation is to preserve the dis- 
 tance from S to O invariable, and not the distance from 
 S toC. 
 
 The distance of the centre of oscillation varies with the 
 length of the cylinder F B, and hence suffers an alteration 
 in its distance from the point of suspension by the elongation 
 of the cylinder, although the distance of the centre of gravity 
 C from the point of suspension remains unaltered. 
 
 We shall endeavor to render this perfectly familiar. Sup- 
 pose a metallic cylinder, 6 inches long, to be suspended by a 
 thread 36 inches long, thus forming a pendulum in which 
 the distance of the centre of gravity from the point of sus- 
 pension is 39 inches : the centre of oscillation in such a pen- 
 dulum will be nearly one tenth of an inch below the centre 
 of gravity. Now, let us imagine cylindrical portions of equal 
 lengths to be added to each end of the cylinder, until it 
 reaches the point of suspension ; we shall then have a cylin- 
 der of 78 inches in length, the centre of gravity of which 
 will still be at the distance of 39 inches from the point of 
 suspension. But it is well known that the centre of oscilla- 
 tion of such a cylinder is at the distance of about two thirds 
 of its length from the point of suspension. The centre of 
 oscillation, therefore, has been removed, by the elongation of 
 the cylinder, about 13 inches below the centre of gravity, 
 whilst the centre of gravity has remained stationary, 
 
 Now, the same thing as that which we have just described 
 takes place, though in a very minor degree, with our for- 
 mer cylinder, employed as a compensating bob to a pendulum. 
 The rod expands downwards, the centre of gravity remains 
 at the same distance from the point of suspension, and the 
 cylinder elongates both above and below this point ; the con- 
 sequence of which is, that though the centre of gravity has 
 remained stationary, the distance of the centre of oscillation 
 from the point of suspension has increased. It is, therefore, 
 evident that the length of the compensation must be such as 
 to carry the centre of gravity a little nearer to the point of 
 suspension than it was before the expansion took place ; by 
 which means the centre of oscillation will be restored to its 
 former distance from the point of suspension. 
 
 Let us suppose the expansions to have taken place, and that, 
 the centre of gravity remaining at the same distance from 
 the point of suspension, the centre of oscillation is removed 
 to a greater distance, as we have before explained. It is 
 
CHAP. xxi. GRAHAM'S PENDULUM. 277 
 
 well known that the product obtained by multiplying the dis- 
 tance from the point of suspension to the centre of gravity, 
 by the distance from the centre of gravity to the centre of 
 oscillation, is a constant quantity ; if, therefore, the distance 
 from the centre of gravity to the point of suspension be 
 lessened, the distance from the centre of gravity to the cen- 
 tre of oscillation will be proportionally, though not equally, 
 increased, and the centre of oscillation will, therefore, be 
 elevated. We see, then, if we elevate the centre of gravity 
 precisely the requisite quantity, by employing a sufficient 
 length of the compensating material, that although the dis- 
 tance from the centre of gravity to the point of suspension 
 is lessened., yet the distance from the point of suspension 
 to the centre of oscillation will suffer no change. 
 
 The following rule for finding the length of the compen- 
 sating material, in a pendulum of the kind we have been con- 
 sidering, will be found sufficiently accurate for all practical 
 purposes : 
 
 Find, in the manner before directed, the length of the com- 
 pensating material, the expansion of which will be equal to 
 that of the rod of the pendulum. Double this length, and 
 increase the product by its one tenth part, which will give the 
 total length required. We shall give examples of this as we 
 proceed. 
 
 Graham's Mercurial Pendulum. 
 
 It was in the year 1721 that Graham first put up a pendu 
 lum of this description, and subjected it to the test of ex- 
 periment ; but it appears to have been afterwards set aside 
 to make way for Harrison's gridiron pendulum, or for others 
 of a similar description. For some years past, however, its 
 merits have been more generally known, and it is not sur- 
 prising that it should be considered as preferable to others, 
 both from the simplicity of its construction, and the perfect 
 ease with which the compensation may be adjusted. 
 
 We have already alluded to Mr. Baily's very able paper on 
 this pendulum, and we shall take the liberty of extracting 
 from it the following description : 
 
 At Jig. 223. is a drawing of the mercurial pendulum, as 
 constructed in the manner proposed by Mr. Baily. 
 
 " The rod S F is made of steel, and perfectly straight ; its 
 24 
 
278 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 form may be either cylindrical, of about a quarter of an inch 
 in diameter, or a flat bar, three eighths of an inch wide, 
 and one eighth of an inch thick : its length from S to F, 
 that is, from the bottom of the spring to the bottom of 
 the rod at F, should be 34 inches. The lower part of 
 this rod, which passes through the top of the stirrup, 
 and about half an inch above and below the same, must 
 be formed into a coarse and deep screw, about two tenths 
 of an inch in diameter, and having about thirty turns in 
 an inch. A steel nut with a milled head must be placed 
 at the end of the rod, in order so support the stirrup ; and a 
 similar nut must also be placed on the rod above the head of 
 the stirrup, in order to screw firmly down on the same, and 
 thus secure it in its position, after it has been adjusted nearly 
 to the required rate. These nuts are represented at B and C 
 A small slit is cut in the rod, where it passes through the 
 head of the stirrup, through which a steel pin E is screwed, 
 in order to keep the stirrup from turning round on the rod. 
 The stirrup itself is also made of steel, and the side-pieces 
 should be of the same form as the rod, in order that they 
 may readily acquire the same temperature. The top of the 
 stirrup consists of a flat piece of steel, shaped as in the draw- 
 ing, somewhat more than three eighths of an inch thick. 
 Through the middle of the top (which at this part is about 
 one inch deep) a hole must be drilled sufficiently large to 
 enable the screw of the rod to pass freely, but without shak- 
 ing. The inside height of the stirrup from A to D may be 
 8 inches, and the inside width between the bars about three 
 inches. The bottom piece should be about three eighths 
 of an inch thick, and hollowed out nearly a quarter of an 
 inch deep, so as to admit the glass cylinder freely. This 
 glass cylinder should have a brass or iron cover G, which 
 should fit the mouth of it freely, with a shoulder projecting 
 on each side, by means of which it should be screwed to the 
 side-bars of the stirrup, and thus be secured always in the 
 same position. This cap should not press on the glass cylin- 
 der, so as to prevent its expansion. The measures above 
 given may require a slight modification, according to the 
 weight of the mercury employed, and the magnitude of the 
 cylinder : the final adjustment, however, may be safely left 
 to the artist. Some persons have recommended that a circu- 
 lar piece of thick plate glass should float on the mercury, in 
 
 
CHAP. XXI. BAILY ON GRAHAM'S PENDULUM. 279 
 
 order to preserve its surface uniformly level.* The part at 
 the bottom marked H is a piece of brass fastened with 
 screws to the front of the bottom of the stirrup, through a 
 small hole, in which a steel wire or common needle is passed, 
 in order to indicate (on a scale affixed to the case of the 
 clock) the arc of vibration. This wire should merely rest 
 in the hole, whereby it may be easily removed when it is re- 
 quired to detach the pendulum from the clock, in order that 
 the stirrup might then stand securely on its base. One of 
 the screw holes should be rather larger than the body of 
 the screw, in order to admit of a small adjustment, in case 
 the steel wire should not stand exactly perpendicular to the 
 axis of motion. The scale should be divided into degrees, 
 and not inches, observing that with a radius of 44 inches (the 
 estimated distance from the bend of the spring to the end of 
 the steel wire) the length of each degree on the scale must 
 be 0-768 inch." 
 
 In order to determine the length of the mercurial column 
 necessary to form the compensation for this pendulum, we 
 must proceed in the following manner : 
 
 Let us suppose the length of the steel rod and stirrup to- 
 gether to be 42 inches. The absolute expansion of the 
 mercury is -00010010 ; but it is not the absolute expansion, 
 but the vertical expansion in a glass cylinder, which is re- 
 quired, and this will evidently be influenced by the expansion 
 of the base of the cylinder. It is easily demonstrable that, 
 if we multiply the linear expansion of any substance (always 
 supposed to be a very small part of its length) by 3> we may 
 in all cases take the result for the cubical or absolute expan- 
 sion of such substance. In like manner, if we multiply the 
 linear expansion by 2, we shall have the superficial expan- 
 sion. 
 
 If we want the apparent expansion of mercury, the abso- 
 lute or cubical expansion of the glass vessel must be deduct- 
 ed from the absolute expansion of the mercury, which will 
 leave its excess or apparent expansion. In like manner, 
 
 * The variation produced in Ihe height of the column of mercury (supposed 
 to be 6-5 inches high) by an alteration of 16 in the temperature will be 
 only dt O'Ol of an inch, or, in other words, 0-01 of an inch will be the total 
 variation from its mean state, by an alteration of 32 in the temperature. It is 
 therefore probable that inmost cases of moderate alteration in the temperature, 
 the centre only of the column of mercury is subject to elevation and depres- 
 sion, whilst the exterior parts remain attached to the sides of the glass vessel. 
 It was with a view to obviate this inconvenience that Henry Browne, Esq. 
 of -Portland Place (I believe) first suggested the piece of floating glass. 
 
280 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 deducting the superficial expansion of glass from the abso- 
 lute expansion of mercury, we shall have its relative vertical 
 expansion. Now, taking the rate of expansion of glass to 
 be -00000479, and multiplying it by 2, the relative vertical 
 expansion of the mercury in the glass cylinder will be 
 00010010 -00000958 = -00009052. 
 
 The expansion of a steel rod, according to our table, is 
 0000063596 ; which, divided by -00009052, gives -0703 for 
 the length of a column of mercury, the expansion of which is 
 equal to that of a steel rod whose length is unity. 
 
 We have now to multiply 42 inches by -0703, which gives 
 2 - 95 inches; and this, deducted from 42, leaves 39*1 inches; 
 so that the length of rod we have chosen is sufficiently near 
 the truth. Now, double 2-95 inches, and add one tenth of 
 its product, and we shall have 6-49 inches for the length of 
 the mercurial column forming the requisite compensation. 
 Mr. Baily's more accurate calculation gives 6'31 inches. 
 
 A mercurial compensation pendulum may be formed, hav- 
 ing a cylinder of steel or iron, with its top constructed in the 
 same manner as the top of the stirrup, so as to receive the 
 screw of the rod. To find the length of the mercurial 
 column necessary in a pendulum of this description (that is, 
 with a cylinder made of steel), we must double the linear 
 expansion of steel, and take it from the absolute expansion 
 of mercury, to obtain the relative vertical expansion of the mer- 
 cury. This will be -00010010 -00001272 = -00008738; 
 
 ,. , f. -0000063596 r\~/c\*tt\ 
 
 and, proceeding as before, we have . 00008738 '0/279. 
 
 Let the length of the steel rod be, as before, 42 inches. 
 Multiplying this by -07279, we have 3-057, which being 
 doubled, and one tenth of the product added, we obtain 
 6-72 inches for the length of the compensating mercurial 
 column ; which Mr. Baily states to be 6-59. 
 
 A mercurial compensation pendulum, having a rod of glass, 
 has been employed by the writer of this article, who has had 
 reason to think well of its performance. Its cheapness and 
 simplicity much recommend it. It is merely a cylinder of 
 glass of about 7 inches in depth, and 2 inches diameter, 
 terminated by a long neck, which forms the rod of the pen- 
 dulum, the whole blown in one piece. A cap of brass is 
 clamped by means of screws to the top of the rod, and to 
 this the pendulum spring is pinned. 
 
 We have unquestionable authority for saying, that the 
 
CHAP. XXI. COMPENSATION PENDULUM. 281 
 
 mercurial pendulum of the usual construction, that is, with 
 a steel rod and glass cylinder, is not affected by a change of 
 temperature simultaneously in all its parts. Now, the pen- 
 dulum of which we are treating being formed throughout of 
 the same material in a single piece, and in every part of the 
 same thickness, it is presumed it cannot expand in a linear 
 direction, until the temperature has penetrated to the whole 
 interior surface of the glass, when it is rapidly diffused 
 through the mass of mercury. M. Biot mentions that a 
 pendulum of this kind was formerly used in France, and 
 expresses his surprise that it was no longer employed, as 
 he had heard it very highly spoken of. The writer of this 
 article has also used a pendulum with a glass rod, which 
 differs from that we have just mentioned, in having the lower 
 end of the rod firmly fixed in a socket attached to the centre 
 of a circular iron plate, on the circumference of which a 
 screw is cut, which fits into a collar of iron, supporting the 
 cylinder (to which^t is cemented) by. means of a circular lip 
 This arrangement, though perhaps less perfect than that 
 we have just described, the pendulum not being in one piece, 
 has the advantage of allowing a circular plate of glass to be 
 placed upon the surface of the mercury, as practised by Mr. 
 Browne. To determine the length of a column of mercury 
 for a glass pendulum, let us suppose the glass, including the 
 cylinder, to be 41 inches in length. Multiplying this by 
 0529, the number taken from Table II. for a glass rod and 
 mercury in a glass cylinder, we have 2*17 inches for the un- 
 corrected length of mercury, which compensates 41 inches 
 of glass. Suppose the steel spring to be one inch and a half 
 long : multiplying this by -0703, the appropriate decimaj 
 taken from Table II., we haveO'l, the length of mercury 
 -me to the steel, making with the former 2*27 inches, which 
 being doubled, and the product increased by its one tenth 
 part, we obtain five inches for the length of the required 
 column of mercury. 
 
 Compensation Pendulum of Wood and Lead, on the Princi- 
 ple of the Mercurial Pendulum. 
 
 If by any contrivance wood could be rendered impervious 
 to moisture, it would afford one of the most convenient sub- 
 stances known for a compensation pendulum. It does not 
 appear that sufficient experiments have been made upon this 
 
 24* 
 
282 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 subject to decide the question. Mr. Browne of Portland 
 Place, who has devoted much of his time and attention to the 
 most delicate inquiries of this kind, has, we believe, found 
 that if a teak rod is well gilded, it will not afterwards be 
 affected by moisture. At all events, it makes a far superior 
 pendulum, when thus prepared, to what it does when such 
 preparation is omitted. 
 
 Mr. Daily, in the paper we have before alluded to, pro- 
 poses an economical pendulum to be constructed by means 
 of a leaden cylinder and a deal. rod. He prefers lead to 
 zinc, on account of its inferior price, and the ease with 
 which it may be formed into the required shape ; and as 
 there is no considerable difference in their rates of expansion, 
 it is equally applicable to the purpose. 
 
 Let the length of the deal rod be taken at 46 inches. 
 Then, to find the length of the cylinder of lead to compen- 
 sate this, we have, in Table II., -1427 for such a pendulum ; 
 which, being multiplied by 40, the product doubled, and one 
 tenth of the result added to it, gives 14-44 inches for the 
 length of the leaden cylinder. Mr. Baily's compensation 
 gives 14-3 inches. 
 
 The rod is recommended to be made of about three 
 eighths of an inch in diameter : the leaden cylinder is to be 
 cast with a hole through its centre, which will admit with 
 perfect freedom the cylindrical end of the rod. The cylinder 
 is supported upon a nut, which screws on the end of the rod 
 in the usual manner. This pendulum is represented at 
 fig- 224. 
 
 Mr. Baily proposes that the pendulum should be adjusted 
 nearly to the given rate by means of the screw at the bottom, 
 and that the final adjustment be made by means of a slider 
 moving along the rod. Indeed, this is a means of adjust- 
 ment which we would recommend to be employed in every 
 pendulum. 
 
 Smeaton's Pendulum. 
 
 We shall conclude our account of compensation pendulums 
 with a description of that invented by Mr. Smeaton. The 
 compensation for temperature in this pendulum is effected 
 by combining the two modes, which have been so fully de- 
 scribed in the preceding part of this article. 
 
 The pendulum rod is of solid glass, and is furnished with a 
 steel crew and nut at the bottom in the usual manner. Upon 
 
CHAP. xxi. SMEATON'S PENDULUM. 283 
 
 the glass rod a hollow cylinder of zinc, about the eighth of 
 an inch thick, and about 12 inches long, passes freely, and 
 rests upon the nut at the bottom of the pendulum rod. 
 
 Over the zinc cylinder passes a tube made of sheet-iron. 
 The edge of this tube at the top is turned inwards, and is 
 notched so as to allow of this being effected. A flanche is 
 thus formed, by which the iron tube is supported, upon the 
 zinc cylinder. The lower edge of the iron tube is turned 
 outwards, so as to form a base destined to support a leaden 
 cylinder, which we are about to describe. 
 
 A cylinder of lead, rather more than 12 inches long, is 
 cast with a hole through its axis, of such a diameter as to 
 allow of its sliding freely, but without shake, upon the iron 
 tube over which it passes, and by the lower extremity of 
 which it is supported. 
 
 Now the zinc, resting upon the nut, and expanding up- 
 wards, will raise the whole of the remaining part of the 
 compensation. This expansion upwards will be slightly 
 counteracted by the lesser expansion downwards of the iron 
 tube, which carries with it the leaden cylinder. The cylin- 
 der of lead now acts upon the principle of the mercurial 
 pendulum, and, expanding upwards, contributes that which 
 was wanting to restore the centre of oscillation to its proper 
 distance from the point of suspension. 
 
 This pendulum, we have been informed, does well in prac- 
 tice, and we are not aware that a*y description of it has been 
 before published. 
 
 The method of calculating the length of the tubes required 
 to form the compensation, is very simple ; nothing more is 
 necessary than to find the length of zinc, the expansion of 
 which is equal to that of the pendulum rod. 
 
 Let the pendulum rod be composed of 43 inches of glass, 
 the spring being an inch and a half long, and the screw be- 
 tween the end of the glass rod and the nut half an inch, 
 making in the whole two inches of steel and 43 inches of 
 glass. 
 
 Now, to find the length of zinc that will compensate the 
 glass, we have, from Table II., for glass and zinc -2773, 
 which multiplied by 43, gives 11*92 inches. In like manner 
 we obtain as a compensation for two inches of steel 0*74 of 
 zinc, which, added to 11-92, gives 12-66 inches for the total 
 length of the zinc cylinder. 
 
 Now, if the iron tube and the lead cylinder be each made 
 
284 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 of the same length as the zinc, and arranged as we have 
 described, the compensation will be perfect. 
 
 To prove this, find, by means of the expansions given in 
 Table I., the actual expansion of each of the substances em- 
 ployed in the pendulum, and we shall have the following 
 results : 
 
 The expansion of 12*66 inches of zinc expanding 
 
 upwards is -0002186 
 
 Deduct that of 12-66 inches of iron expanding 
 
 downwards . . -0000869 
 
 Remaining effect of expansion upwards, referred 
 
 to the lower extremity of the iron tube -0001317 
 
 Now, for the lead. On the principle of the mer- 
 curial compensation, subtract one tenth part of 
 the length of the cylinder, and take half the 
 remainder, and we shall have six inches of lead, 
 the expansion of which upwards is -0000955 
 
 Total expansion of the compensation upwards . . -0002272 
 
 To find the expansion of the rod, we have the ex- 
 pansion of 43 inches of glass -0002059 
 
 Of two inches of steel . -0000127 
 
 Total expansion of the pendulum rod -0002186 
 
 Agreeing near enough with that of the compensation before 
 found. 
 
 As we conceive we have been sufficiently explicit in our 
 description of this pendulum, in the construction of which 
 no difficulty presents itself, we think an engraved representa- 
 tion of it would be superfluous. 
 
 We have hitherto treated only of compensations for tem- 
 perature ; but there is another kind of error, which has been 
 sometimes insisted upon, arising from a variation in the 
 density of the atmosphere. If the density of the atmos- 
 phere be increased, the pendulum will experience a greater 
 resistance, the arc of vibration will in consequence be dimin- 
 ished, and the pendulum will vibrate faster. This, however, 
 is in some measure counteracted by the increased buoyancy 
 of the atmosphere, which, acting in opposition to gravity, 
 
CHAP. XXI. PENDULUMS. 285 
 
 occasions the pendulum to vibrate slower. If the one effect 
 exactly equalled the other, it is evident no error would arise ; 
 and in a paper by Mr. Davies Gilbert, President of the Royal 
 Society of London, published in the Quarterly Journal for 
 1826, he has proved that, by a happy chance, the arc in 
 which pendulums of clocks are usually made to vibrate, is the 
 arc at which this compensation of error takes place. This 
 arc, for a pendulum having a brass bob, is 1 56' 30" on each 
 side of the perpendicular ; and for a mercurial pendulum, 
 1 31' 44", or about one degree and a half. 
 
 It is well known that, if a pendulum vibrates in a circular 
 arc, the times of vibration will vary nearly as the squares of 
 the arcs; but if the pendulum could be made to vibrate in a 
 cycloid, the time of its vibration in arcs of different extent 
 would then remain the same. Huygens and others, therefore, 
 endeavored to effect this by placing the spring of the pendu-" 
 lum between checks of a cycloidal form. 
 
 When escapements are employed which do not insure an 
 unvarying impulse to the pendulum, the force may be un- 
 equally transmitted through the train of the clock in conse- 
 quence of unavoidable imperfections of workmanship, and 
 the arc of vibration may suffer some increase or diminution 
 from this cause. To discover a remedy for this is certainly 
 desirable. 
 
 The writer of this article some years ago imagined a 
 mode, which he believes has also been suggested by others, 
 by which he conceived a pendulum might be made to de- 
 scribe an arc approaching in form to that of a cycloid. The 
 pendulum spring was of a triangular form, and the point or 
 vertex was pinned into the top of the pendulum rod, the base 
 of the triangle forming the axis of suspension. Now, it is 
 evident that when the pendulum is in motion, the spring will 
 resist bending at the axis of suspension, with a force in some 
 sort proportionate to the base of the triangle. 
 
 Suppose the pendulum to have arrived at the extent of its 
 vibrations ; the spring will present a curved appearance ; and 
 if the distance from the point of suspension to the centre of 
 oscillation be then measured, it will evidently, in consequence 
 of the curvature of the spring, be shorter than the distance 
 from the point of suspension to the centre of oscillation, 
 measured when the pendulum is in a perpendicular position, 
 and consequently when the spring is perfectly straight. 
 
 The base of the triangle may be diminished, or the spring 
 
286 THE ELEMENTS OF MECHANICS. CHAP. XXI. 
 
 be made thinner ; either of which will lessen its effect. We 
 cannot say how this plan might answer upon further trial, 
 as sufficient experiments were not made at the time to au- 
 thorize a decisive conclusion. 
 
 We have thus completed our account of compensation 
 pendulums ; but before we conclude, it may not be unaccep- 
 table if we offer a few remarks on some points which may 
 be found of practical utility. 
 
 The cock of the pendulum should be firmly fixed either 
 to the wall or to the case of the clock, and not to the clock 
 itself, as is sometimes done, and which has occasioned much 
 irregularity in its rate, from the motion communicated to the 
 point of suspension. We prefer a bracket or shelf of cast 
 iron or brass, upon which the clock may be fixed, and the 
 cock carrying the pendulum attached to its perpendicular 
 back. This bracket may either be screwed to the back of 
 the clock-case, or, which is the better mode, securely fixed 
 to the wall ; and if the latter be adopted, the whole may be 
 defended from the atmosphere, or from dust, by the clock-case, 
 which thus has no connection either with the clock or with 
 the pendulum. 
 
 The point of suspension should be distinctly defined and 
 immovable. This may be readily effected, after the pendu- 
 lum shall have taken the direction of gravity, by means of a 
 strong screw entering the cock (which should be very stout) 
 on one side, and pressing a flat piece of brass into firm con- 
 tact with the spring. 
 
 The impulse should be given in that plane of the rod 
 which coincides with the plane of vibration passing through 
 the axis of the rod. If the impulse be given at any point 
 either before or behind this plane, the probable result will be 
 a tremulous, unsteady motion of the pendulum. 
 
 A few rough trials, and moving the weight, will bring the 
 pendulum near its intended time of vibration, which should 
 be left a little too slow ; when the bob should be firmly fixed 
 to the rod, if the form of the pendulum will admit of it, by 
 a pin or screw passing through its centre. 
 
 The more delicate adjustment may be completed by shift- 
 ing the place of the slider with which the pendulum is sup- 
 posed to be furnished on the rod. 
 
 Mr. Browne (of whom we have before spoken) practises 
 the following very delicate mode of adjustment for rate, which 
 will be found extremely convenieat, as it is not necessary to 
 
CHAP. XXI. PENDULUMS. 287 
 
 stop the pendulum in order to make the required alteration. 
 Having ascertained, by experiment, the effect produced on 
 the rate of the clock, by placing a weight upon the bob equal 
 to a given number of grains, he prepares certain smaller 
 weights of sheet-lead, which are turned up at the corners, 
 that they may be conveniently laid hold of by a pair of for- 
 ceps, and the effect of these small weights on the rate of the 
 clock will be, of course, known by proportion. The rate 
 being supposed to be in defect, the weights necessary to cor- 
 rect this may be deposited, without difficulty, upon the bob 
 of the pendulum, or upon some convenient plane surface, 
 placed in order to receive them : and should it be necessary 
 to remove any one of the weights, this may readily be done 
 by employing a delicate pair of forceps, without producing 
 the slightest disturbance in the motion of the pendulum. 
 
INDEX. 
 
 A. 
 
 Action and reaction, 29. 
 
 Aeriform fluids, 22. 
 
 Animalcules, 10. 
 
 Atmosphere, impenetrability of, 15. 
 Compressibility and elasticity of, 1C. 
 
 Atoms, 5. Coherence of, 5. 
 
 Attraction, magnetic, of gravitation, 7, 
 41, 53. Molecular or atomic, 57. Co- 
 hesion, 58. 
 
 Attwood, machine of, 76. 
 
 Axes, principal, 117. 
 
 Axis, mechanical properties of, 108. 
 
 B. 
 
 Balance,235. Of Bate, 242. Use of, 213. 
 Danish, 252. Bent-lever of Brady, 253. 
 
 Bodies, 1. Lines, surfaces, edges, area, 
 length of, 3. Figure, volume, shape 
 of, 4. Porosity of, 14. Compressibili- 
 ty of, 16. Elasticity, dilatability of, 16. 
 Inertia of, 23. Rule for determining 
 velocity of motion of two bodies after 
 impact, 32. 
 
 C. 
 
 Capillary attraction, 61. 
 
 Capstan, 151. 
 
 Cause and effect, 6. 
 
 Cir-le of curvature, 84. 
 
 Cog, hunting, 161. 
 
 Components. 42. 
 
 Cord, 139. 
 
 Cordage, friction and rigidity of, 219. 
 
 Crank, 203. 
 
 Crystallization, 12. 
 
 Cycloid, 134. 
 
 D. 
 
 Damper, self-acting, 197. 
 
 Deparcieux's compensation pendulum, 
 
 269. 
 
 Diagonal, 42. 
 Dynamics, 135. 
 Dynamometer, 257. 
 
 Electricity, 63. 
 Eleetro magnetism, 63. 
 Equilibrium, neutral, instable and 
 ble, 99. 
 
 sta- 
 
 Figure, 4. 
 Yly. wheel, 201. 
 
 Force, 5. Composition and resolution 
 of, 41. Centrifugal, 84. Moment of; 
 leverage of, 114. Regulation and ac- 
 cumulation of, 189. 
 
 Friction, effects of, 82. Laws of, 223. 
 
 G. 
 
 Governor, 191. 
 
 Gravitation, attraction of, 64. Terres- 
 trial, 70. 
 
 Gravity, centre of, 90. 
 Gyration, radius of, centre of, 115 
 
 II . 
 
 Hooke's universal joint, 212. 
 Hydrophane, porosity of, 15. 
 
 Impact, 33. 
 Impulse, 53. 
 
 Inclined plane, 138, 176. 
 Inclined roads, 177. 
 
 Inertia, 23. Laws of, 28. Moment of, 
 116. 
 
 J. 
 Julien le Roy , compensation tube of, 268. 
 
 Lever, 138. Fulcrum of; three kinds of, 
 
 141. Equivalent, 148. 
 Line of direction, 93. 
 Liquids, compressibility of, 20. 
 Loadstone, 57. 
 
 M. 
 
 Machines, simple, 135. Power of, 148 
 Regulation of, 189. 
 
 Magnet, 56. 
 
 Magnetic attraction, 7. 
 
 Magnetism, 63. 
 
 Magnitude, 3. 
 
 Marriott's patent weighing machine, 257. 
 
 Materials, strength of, 229. 
 
 Matter, properties of, 1. Impenetrability 
 of, 4. Atoms of; molecules of, 5. 
 Divisibility of, 7. Examples of the 
 subtilty of, 10. Limit to the divisibility 
 of, 11. Porosity of; density of, 14. 
 Compressibility of, 16. Elasticity and 
 dilatability of, 16. Impenetrability of, 
 19. Inertia of, 23. 
 
 Mechanical science, foundation of, 14. 
 
INDEX. 
 
 Metronomes, principles of, 130. 
 
 Molecules, 5. 
 
 Motion, laws of, 38. Uniformly accel- 
 erated, 73. Table illustrative of, 75. 
 Retarded, 78. Of bodies on inclined 
 planes and curves, 79. Rotary and 
 progressive, 107. Mechanical con- 
 trivances for the modification of, 206. 
 Continued rectilinear; reciprocatory 
 rectilinear ; continued circular ; recip- 
 rocating^circular, 207. 
 N. 
 
 Newton, method of, for determining the 
 thickness of transparent substances, 9. 
 Laws of motion of, 38. 
 
 O. 
 
 Oscillation, 109. Of the pendulum, 123. 
 Centre of, 128. 
 
 P. 
 
 Parallelogram. 42. 
 
 Particle, 5. 
 
 Pendulum, oscillation or vibration of, 
 123. Isochronism of, 125. Centre of 
 oscillation of, 124. Of Tronghton, 239. 
 Compensation, 259. Of Harrison, 264. 
 Tubular, of Troughton,264. Of Ben- 
 zenberg, 266. Ward's compensation, 
 
 268. Captain Rater's compensation, 
 
 269. Reid's compensation, 271. Elli- 
 cott's, 272. Steel and brass compensa- 
 tion, 273. Mercurial, 275. Graham's 
 mercurial, 277. Wood and load, 281. 
 Smeaton's,282. 
 
 Percussion, 109. Centre of, 192. 
 
 Planes of cleavage, 13. 
 
 Porosity, 14. 
 
 Power, 136. 
 
 Properties, 1. 
 
 Projectiles, curvilinear path of, 68. 
 
 Pulley, 139. Tackle ; fixed, 167. Single 
 
 movable, 168. Called a runner; 
 
 Spanish bartons, 173. 
 
 R. 
 
 Rail-roads, 177. 
 Regulating damper, 197. 
 
 Regulators, 191. 
 Repulsion, 7. Molecular, 61. 
 Resultant, 42. 
 Rose-engine, 211. 
 
 S. 
 
 Salter, spring balance of, 256. 
 
 Screw, 176. Concave, 183. Microme- 
 ter, 188. 
 
 Shape, 5. 
 
 Spring, 256. 
 
 Statics, 135. 
 
 Steelyard, 248. C. Paul's, 249. Chi- 
 nese, 252. 
 
 Syphon, capillary, 61. 
 
 T. 
 
 Table, whirling, 85. 
 Tachometer, 197. 
 Tread-mill, 151. 
 
 V. 
 
 Velocity, angular, 84. 
 
 Vibration, 109. Of the pendulum, 123. 
 
 Centre of, 128. 
 Volume, 4, 14. 
 
 W. 
 
 Watch, main-spring of; balance-wheel 
 of, 164. 
 
 Water regulator, 193. 
 
 Wedge, 176. Use of, 180. 
 
 Weight, 136. 
 
 Weighing machines, 234. For turnpike- 
 roads, 254. By means of a spring, 255. 
 
 Wheels, spur, crown, bevelled, 159. Es- 
 capement, 164. 
 
 Wheel and axle, 149 
 
 Wheel- work, 149. 
 
 Winch, 151. 
 
 Windlass, 151. 
 
 Wollaston's wire, 9. 
 
 Z. 
 
 Zureda, apparatus of; Leupold'd appli- 
 cation of, 211. 
 
 THE END. 
 
pun 
 
PL. VII 
 

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14 DAY USE 
 
 RETURN TO DESK FROM WHICH BORROWED 
 
 LOAN DEPT. 
 
 This book is due on the last 
 
 the date 
 
 i 1972 70 
 
 
 LD21A-60m-8,'70 
 (N8837slO)476 A-32 
 
 General Library 
 
 University of Californis 
 
 Berkeley 
 
UNIVERSITY OF CALIFORNIA LIBRARY