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TJ
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ARTES
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VERITAS
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TJ
144
.B22
1815
1
A
Treatise on Mills,
IN FOUR PARTS.
FART FIRST,
ON CIRCULAR MOTION.
PART SECOND,
ON THE MAXIMUM OF MOVING BODIES, MACHINES,
ENGINES, &c.
PART THIRD,
ON THE VELOCITY OF EFFLUENT WATER.
PART FOURTH,
EXPERIMENTS ON CIRCULAR MOTION, WATER
WHEELS, &c.
BY JOHN BANKS,
LECTURER IN EXPERIMENTAL PHILOSOPHY.
Second Edition.
THEY CONTINUE THIS DAY ACCORDING TO THINE ORDInances.
I
LONDON:
PSALM exix. 91.
PRINTED FOR LONGMAN, Hurst, rees, orme, and browne;
AND FOR
W. GRAPEL, LIVERPOOL.
1815.

E.
S.
MAY
21
U. E. S. DUPLICĂ:
1926
LIBRAR
Printed by G. F. Harris's Widow and Brothers,
Water-street, Liverpool
I
霉
​J
7
JM. F.
уга
Transporte
Preface.
THE experiments contained in the fourth part of this
treatise, and some of these in the third, have been the
subject of a public lecture, which I have occasionally
delivered, for about twenty years. At the request of
many of my hearers, I have made it public; and have
prefixed a few problems on circular motion, &c. For
in order to know the powers of different wheels, or
which is best able to overcome an obstacle, it is neces-
sary to know their central forces.
Where different powers are compared, as in Prob.
XII, &c. they are supposed to act upon the wheel, while
they descend through the same space. When a wheel
or fly, of any given weight or magnitude, has received a
given degree of velocity, no more power is required to
continue that velocity than what is sufficient to overcome
the friction. Yet if it moves twice as fast, it will require
four times the former power to continue that motion:
hence, one would be apt to infer, that the friction in-
creases with the square of the velocity. In a water-
wheel, the same power is not constant; for the same
particles act upon the wheel during only a part of a re-
3
iv
THE PREFACE.
volution; their places are constantly supplied, or they
are succeeded by others which act for their time, &c.:
hence, a water-wheel soon acquires an uniform velocity.
In the second part, the third problem has three
solutions; the two first on principles the most common,
but not perfectly just; but as they are sufficiently near
in practice, and much easier than the third, they are
continued till the eighth problem, inclusive, which, in
fact, is but one problem, for the fourth, &c. are illus-
trations of the theorems drawn from the third, and ought
rather to have been examples. In this, as well as in
many of the following problems, I have endeavoured to
shew the impossibility of a given power producing more
than a given effect, or of raising more than a certain
quantity of water, weight, &c. to a given altitude, in a
limited time. For, in this case, combinations of ma-
chinery afford no assistance, but the contrary. For if
one pound in one scale cannot raise one pound in the
other, we shall get nothing by suspending a weight from
the circumference of a wheel, in order to raise a greater
at the circumference of its axle. For if the machine is
so constructed that one pound will raise ten pounds, the
pound must descend more than ten times as fast as the
other rises, and of consequence it must descend more
than ten successive times through a given space, to raise
ten pounds through the same space.
It is true, that we have in the kingdom many intel-
ligent engineers, and excellent mechanics; and there are
others who can execute better than they can design,
otherwise there would not have been so much money
expended in attempting what men of science know to be
impossible.
THE PREFACE.
When a man tells me he can construct a water-wheel
in such a manner that, when once put in motion, it shall
raise water to keep itself moving; or that he has con-
structed a pump in such a manner, that one man may
do the work of ten, &c. I pay the same attention to him,
as if he told me he could create a system of worlds, and
command them to move. Or, is he less to be credited
who says he can communicate perpetual motion to dead
matter? Both are indirectly saying, I can reverse the
laws of nature.
Many of the problems in this part are intended not
only to prove that a given power can only produce a
given effect, but at the same time to demonstrate what
the greatest effect is which a given power can produce.
For a power is often applied in such a manuer as to cause
the effect to fall short of the maximum, as demonstrated
in the third problem, when the time is given, and in the
thirty-fifth, &c. when the space is given, where it ap-
pears, that if the power and resistance be equally dis-
tant from the centre, in case of a maximum, or when
the power produces the greatest possible effect, the for-
mer will be to the latter as 1000 to 618. Or if the
power be applied ten times as far from the centre as the
resistance, when reduced they will be as 1000 to 659,
the weight of the machine not considered, for which see
Prob. XXXVII, XXXVIII, &c. When the power and
resistance are both given, by Prob. XXX, a machine
may be constructed, by which the power shall produce
the greatest effect in a given time.
In the third part, the experiments on effluent water
differ considerably from any theory; and, contrary to
expectation, more water is discharged, in proportion,
1
i
!
:
vi
THE PREFACE.
from small than from large apertures. The quantity
through small holes, I have endeavoured to ascertain,
by different processes, all of which bring out nearly the
same conclusions. And though I have had much prac-
tice in making experiments, I have not trusted entirely
to my own observations, but have been assisted in the
whole by one or more gentlemen well acquainted with
the subject. At Coventry, by the Rev. Mr. Banks, of
Monks Kirkby; by Messrs. Baines, Watson, Dicas, &c.
of Liverpool; by Mr. Priestly, and Mr. Peckover, of
Bradford; by my eldest son, and by my wife, who,
though a woman, is perhaps as accurate in making ex-
periments in philosophy, and some branches of chemis-
try, as most of men. Upon the whole, I presume the
rules contained in this part, for finding the quantity of
water discharged in a given time, will be found suffici-
ently accurate in practice.
:
•
However satisfactory mathematical reasoning may
be to some, yet experimental proof is desirable, and, to
many, much more so than the former; and without ex-
periments, we often want data to reason from. But if
we have certain principles, the conclusions drawn there-
from will often differ considerably from experiment, or
rather the experiment from the theory. For the theory
supposes the bodies to move in free space, without fric-
tion, or any kind of resistance; but as these impediments
cannot be entirely removed, the experiments cannot
perfectly coincide with the theory, though in some cases
they come exceedingly near.
In the fourth part, the experiments on circular
motion, &c. are sufficiently accurate to prove the truth
of the theory, and the utility thereof, when applied to
THE PREFACE.
vii
the construction of machines. I have thought the pre-
ceding theory and experiments a necessary introduction
to the principal subject, the experiments on wheels, &c.;
in which I have endeavoured to investigate the truth,
without a view to support any particular system, senti-
ments, or opinion. And if some of the experiments
happen to recommend any construction or application
different to the practice of some professional men, it
might be well to enquire into the foundation of their
practice, whether it is supported by experiments, or
whether it rests upon the opinions of their predecessors.
To rest satisfied with the opinions of others, however
great their reputation, tends much to retard the progress
of knowledge; for error is often found in high places.
❤
It will not be expected that I should attempt to in-
struct the mechanic how to form his cogs, divide the
wheels, proportion their diameters, bevels, &c. as num-
bers of men may be found who can both plan and exe-
cute these parts well. The chief end in view is, how to
make the most of a given stream; and what the experi-
ments recommend, has long since been put in practice,
with acknowledged advantage. If this treatise, in pro-
portion to its sale, proves equally useful with the public
lecture, I shall be satisfied.
To conclude: if, through mistake, I have advanced
any thing erroneous in theory, or drawn any false con-
clusions from the experiments, I hope those who discover
them will candidly correct them.
JANUARY 29th, 1795.
:
A
Treatise on Mills.
PART I..
OF THE LAWS OF CIRCULAR MOTION, THE RATIOS OF PROJEC-
TILE AND CENTRIFUGAL FORCES, THE PERIODIC TIMES, &C.
FIG. I.
In the larger circle,
DEAD the diameter in feet.
VAG the projectile force, or orbit velo-
city in feet.
ABC AE the space through which the
body would move towards the centre, while it
is describing ac, or the central force compared
with the projectile.
B
2
PART FIRST.
FBC the centrifugal force compared with
gravity, or with the weight of the revolving
body, when on the surface of the earth.
T= the periodic time, or time of a revolu-
tion, in seconds.
p the time describing AE or Ac..
s=16 feet, the space through which a body
falls in 1 second.
q=3.1416, the circumference of a circle,
when the diameter is 1.
In the lesser circle,
dad the diameter.
v=ac the velocity.
a=ae the central force, &c.
f=ae=bc.
t-the time of a revolution.
Every body in motion endeavours to move
in a straight line; the force which causes it to
leave that line is called the centripetal, and the
resistance which it affords the centrifugal force.
1. If a body at a, moving towards B, is drawn
to C, BC represents the centrifugal force, and
AE the centripetal force, which are equal; and
as AE is to AC, so is the centrifugal to the
jectile force, or circular velocity.
pro-
ON CENTRAL FORCES.
3
2. From the property of the circle,
AS AD: AC :: AC: AE=
V2
Or, As D: V:: V =A.
D
A C²
A.
AD
3. And in equable motion it will be,
As the time of a revolution is to the cir-
cumference of the orbit, so is any other time
to the space passed over in that time; or so is
1 second to the velocity per second.
Viz. As T: Dq:: P:
Dap
=V.
T
Dqp
T
for its equal AC or v
we have, As D:
Dqp
Dqp Dq2p²
AEA.
T
T
T2
And by substituting
Or, As D: V:
v²
V: =AE=A.
D
4. Also, As 12": s:: p': sp², the space
through which a body near the surface of the
earth would fall in the time p.
5. Then, to compare the centrifugal force
with the gravity, or weight of the revolving
body, which put=1.
It will be, As sp²: AE:: 1: CF.
AE
sp
Or, As sp³:
Dq²p²
T2
Dg2
I: =}.
ST2
jz
Or, As sp²:
I:
CF.
B
SDp2
4
PART FIRST.
When the central force is equal to the weight
Dq²
of the body, =
ST2
second; also As.
1, and sp² = 16, if p = 1
From these proportions we obtain the fol-
lowing Theorems:
Theo. 1. A
=
vq
Dq²
CSF.
D
T
T2
Dq
T
Theo. 2. V=√ADFDS.
11
yq
SF.
Theo. 3. T-
vq
D
SF
V2
T2A
SFT2
Theo. 4. D
A
SF
q²
q²
Dq²
A2D
Theo. 5. F
ST2 Sv2
SD S.
6. If two bodies, in different circles, revolve
in the same time, the velocities will be directly
as the diameters of the circles. (T=t.).
For, As Dq: V (AC) :: dq: v (ac) = vd;
and, As Dd: v: v=
vd
D.
*
Q. E. D.
And, As AC: AE :: ac: ae.
Or, As v : A v: a=
UF
Αν
V.
Or, As v F: v : "==ƒ.
V
Hence, As vv :: Ff:: D: d.
D
ON CENTRAL FORCES.
5
E
From which it appears that, if the times are
equal, the central force is directly as the dia-
meter.
7. If vv, then Dq : dq :: T :
Therefore, As D: d:: T: t.
D d
And, As : :V:V=
Tt
rd
D
vdr
Dt.
D d
FdT
: F:ƒ=
and because F is as we
Tt
Dt.
D
v2
D
have, As F:f::. Or,
2
As DF: df :: v²: v², and v :v ::√ DF : √df.
D
D
d
And being as v, we have √df = √DF.
-
T
T
Òr, from the fifth Theorem, if r=t.
:: F:
r:f=
Dq² dq²
As :
ST2 ST2
vd
Theo. 6. v=
D.
rd
f
D.
Theo. 7. d=
Theo. 8. a=
VD
V.
v2d
D.
v¹d
Theo. 9. f= SD.
8. If the diameter remains the same; or if
D=d,
;
6
PART FIRST.
Then, As
Dq²
Dq²
ST2 ST2
FT2
: F: =ƒf, and as t²:
t²
T² : : F : ƒ : : v²: v², or the central forces, in
the same circle, are reciprocally as the squares
of the times; or directly as the squares of the
velocities.
Theo. 10. f=
FT2
Theo. 11. t–V Fr
9. When F=ƒ;
Dq² ____ dq²
ST2 st2
"
or Dt² dr².
D
And =
T2 t²
Dt2
(see Theo. 5.)
=d.
T²
d
And, As T': :: D: d, or T: t::VD:vd.
Dt2
T2
Theo. 12. d when the times are given.
Theo. 13. t = Ty
I when the distances are
D
1
given.
The foregoing Theory exemplified, in the solution
of various Problems in circular motion.
PROBLEM I.
Given the diameter of the orbit, 10 feet, and
the centrifugal force equal to the weight of the
ON CENTRAL FORCES.
7
revolving body; required the time of a revo-
lution, and velocity per second?
In this case, A=s; and FI (see Art. 5.)
D
In Theo. 3. we have T = q√3.1416/10
Tq =
=2.4818"; and per Theo. 2. v =
= √FDS = √160≈ 12.6491.
:
16
Dq 31.416
Ꭲ 2.4818
PROBLEM II.
Given the time of a revolution, 3 seconds,
the central force, 1; required the distance,
and velocity?
་
T= 3.
T²s
144
Theo. 4. D=
= 14.59
F = 1.
q²
9.8696
feet; half of which is the distance, -7.295 feet.
And v✓ FDS 15.279 feet
FDS = 15.279 feet per second.
PROBLEM III.
Given the diameter and periodic time, to
find the central force and velocity?
14.59.
Dq²
144
T=3″.
(Theo. 5.) F= ===1.
ST2
144
Dq
V= =
T
45.837
3
= 15.279 feet.
8
PART FIRST.
1
PROBLEM IV.
:
Given the diameter, 14.59 feet, and the ve-
locity, 15.279, to find the periodic time and
central force?
Dg 45.837
(Per Theo. 3.) T=
=3".
3″.
V 15.279
233.44
(Per Theo. 5.) F=
= 1.
SD
16 x 14.59
PROBLEM V.
Given the diameter, 14.59 feet, the central
force equal to twice the weight of the body;
what is the velocity, and time of a revolution?
Т
T = qv
DV
2FS
14.59
32
x q = .6753 × 9 =
2.1214".
v = √2FDS = 21.6074 feet per second.
Or if we compare this problem with the last,
we have (8)
As f: F: T²: t, or t TV
TV F
2.12, &c.
=
=
3√.
2
And, As F : ƒ : : 'v² : v² = 7, or v = v√‡
✓
= 15.279 X V
F
= 15.279 X 1.414, &c. =
21.607.
ON CENTRAL FORCES.
9
PROBLEM VI.
Let the diameter be 29.18 feet, (twice as
much as in Prob. III.) the time of a revolution
3 seconds; required the velocity, and central
force?
Dq _____ 91.671
V=
=30.5572.
T
3
Dq2 288
F =
=2.
ST2 144
vd
(Art. 6.) As D: d::v :v=
30.5572.
D
Viz. As 14.59: 29.18 :: 15.279: 30.5572.
Again, As D: d : : r : f=dr
D
As 14.59 29.18 : 2, the centrifugal
force, the same as above.
PROBLEM VII.
The stones on which they grind table knives
at Sheffield, are about 44 inches diameter, and
weigh about half a ton; the velocity of the
surface is at the rate of 1250 yards in a minute,
equal to 326 revolutions; required the centri-
fugal force, or the tendency which the stones
have to burst?
D=2.59 feet, the diameter of the circle of
gyration.
C
10
PART FIRST.
!
*
T.184 seconds, the time of one revolution.
2
T² =.033856.
F = D17
Dq²
ST2
==
16 x .0338, &c.
2.59 × 9.8696 25.5622
.54169
= 47.18
times the weight of the stone, or 23 tons.
PROBLEM VIII.
If a fly, 12 feet diameter, and 3 tons weight,
revolves in 8 seconds, and another of the same
weight revolves in 3 seconds; what must be
the diameter of the last, when they have the
same centrifugal force?
D=12.
T=8.
t=3.
F=f.
And
per Theo. 12. dDt²
108
= 1.6875
T2
64
feet, the diameter of the circle of percussion.
N. B. As the weight of each fly is the same,
it does not enter into the solution; but if the
diameters should be the same, as in the next
Problem, the weight must be considered.
PROBLEM IX.
If a fly, 12 feet diameter, revolves in 8 se-
conds, and another of the same diameter in 3
ON CENTRAL FORCES.
fi
•
{
seconds; what are the ratios of their weights,
when the central forces are equal?
Here, F=ƒ, and D=d, which put = 1.
And (Art. 8.) when D=d, we have, As ť:
64
T':: Ff; As 9: 64: 1: = 7, the cen-
9
trifugal force of the second, when they are of
equal weight.
And when the distance and time are the
same, the force is directly as the weight; the
weight of the second will therefore be obtained
by dividing the weight of the first by 73.
PROBLEM X.
If a fly, 2 tons weight, and 16 feet diameter,
is sufficient to regulate an engine, when it re-
volves in 4 seconds; what must be the weight
of one 12 feet diameter, when it revolves in 2
seconds, so that it may have the same power
upon the engine?
=
Here we have D 16; d = 12; T = 4;
t = 2; F = ƒ; suppose d unknown, then, by
Dĺ²
Theo. 12, d= = 4, when the weights are
T2
equal, viz. if the first is 16 feet diameter, and
the second 4 feet, their centrifugal forces would
12
PART FIRST.
be equal; but, by the question, the second is
to be 12 feet diameter, therefore, (whether it
revolves in a circle of 4 feet or 12 feet, the
time is 2 seconds) As D: d:: F:ƒ, (Art. 6.)
viz. As 4:12:: 1: 3=f, but fF by the
question, hence the central force, and, of con-
sequence, the weight is three times too great,
and the second fly ought to be one-third of the
40
weight of the first. 13 cwt.
=
3
Or, the two last Problems may be solved
otherwise.
In Prob. IX. Let w the weight of the first
fly 3 tons. x = the weight of the second.
X
And (Art. 8.) we have t'w=T'x, and x=
t2w
T2
27
60
11
.4218 8.43 cwt.=
as before.
64
71
Dt2w
In Prob. X. we have
= ∞ =
x
dr2
128
192
=.6666
= 13 cwt.
PROBLEM XI.
If a cast-iron fly, 12 feet diameter, and 2
tons weight, has a sufficient centrifugal force
to regulate the pin shaft of a forge-hammer,
when it revolves in 2 seconds; required the
ON CENTRAL FORCES.
13
1
weight of a fly, of the same diameter, that
shall have the same force, when it revolves in
4 seconds?
T = 2; t = 4; D = d; F =ƒ; and w=2;
t2w
hence, == the weight sought
X
T2
16×2
4
8 tons, or four times the weight of the first.
N. B. When the weight of the revolving
body and time of a revolution remain the same,
the central force is directly as the distance from
the centre, or as the diameter of the wheel;
(see Theo. 5.) but if the weight increases with
the distance, or diameter, (and in water-wheels
it often increases in a greater ratio) then the
centrifugal force will be as the square of the
diameter, viz. F is as D
2
D2
T2,
or as
D²q².
ST2
PROBLEM XII.
Let the centrifugal force of a wheel 6 feet
diameter, and that of another of 12 feet dia-
meter, be equal; or, in other words, let the
impelling power be the same, and the first re-
volve in 5 seconds; required the time in which
the second revolves?
Here F =ƒ; D = 6; d = 12; and r = 5.
14
PART FIRST.
By comparing Theo. 13. with the note to
Td
Prob. XI. we get t= = 10 seconds.
D
PROBLEM XIII.
Let the two wheels revolve in the same time;
required the ratio of the impelling powers, or
the central forces?
(See Art. 6.) As D²: d²: : F : ƒ
Fd2 144
D2
Let F1 then =
36
F:ƒ=
f=xd33
= 4.
Viz. the 12 feet wheel requires four times as
much power as the 6 feet wheel, to turn in the
same time.
D2
d2
Otherwise, F =
; f =
; but, As Tt,
t²
F = D², and ƒ=d²; Or,
As F: f:: 36: 144:: 1:4 as before.
PROBLEM XIV.
Given the diameter of a water-wheel, 12 feet,
its weight 2 tons, the time of a revolution 9
seconds; the diameter of the cog-wheel 10
feet, weight 12 cwt.; diameter of mill-stone 6
feet, weight 1 ton, time of a revolution six-
tenths of a second; required the centrifugal
!
ON CENTRAL FORCES.
15
force of the water wheel, cog-wheel, and mill-
stone?
In the water-wheel, D = 12; т = 9; w =
40 cwt. And X w = F =
nq²
ST2
4733
1296
3.65 cwt.
In the cog-wheel, D = 10; T = 9; w = 12.
And
Dqzw
ST2
F
1183
1296
=.91.
In the mill-stone, D = 4 (the diameter of the
circle of percussion;) T =.6; w = 20. And
Dqzw
ST²
789
F= = 137 cwt.
5.76
Water-wheel
Cog-wheel
Mill-stone
-
3.65
.91
-
137.00
Centrifugal force of the whole- 141.56 =
7 tons 1.56 cwt.
In the above computation, it is supposed
that the trundle, which turns the stone, is itself
turned by the cog-wheel; its diameter therefore
could not be more than 9 inches, for which
reason it is not taken into the computation.
PROBLEM XV.
Let the water-wheel and cog-wheel be the
same as in the last Problem, the diameter of the
16
PART FIRST.
trundle 2.5 feet, its weight 2 cwt., and on the
same axis a cog or spur-wheel 10 feet diameter,
and 12 cwt., which turns two trundles each
2.5 feet diameter, and weight together 4 cwt.,
the stones turned by them each 5 feet diameter,
and weight together 36 cwt.; required the cen-
trifugal force of the whole?
The central force of the water and cog-wheel,
as in the last Problem, is 4.56 cwt.
The diameter of the cog-wheel, being di-
vided by that of the trundle, quotes 4; the
number of revolutions that the trundle makes
for one of the water-wheel, one turn in 24
seconds.
And we may take D = of 2.5=1.66; т=
2
Dq2w
2.25; w = 2. And
=F=
ST2
32.774
81
.404
cwt. the force of the trundle.
In the spur-wheel, D= 10; r = 2.25; w=
Dq2
12. And X w =
ST2
force of the spur-wheel.
1183.2
= 14.6 cwt, the
81
The second trundle, or nut, will revolve
four times for the spur-wheel once; therefore,
if we divide 2.25, the time in which the latter
ON CENTRAL FORCES.
17
revolves, by 4, we shall have the time in which
the trundle and stone revolve, .5625 second.
Dqzw
D = 1.66; t =.5625; w=2. And ST2
F = 3.277, which doubled, gives 6.554, the
force of the two trundles.
Lastly, for the force of the stones, we have
Dq²
And Dq2
D = 3.33; t = .5625; w = 18. And
ST2
F=117, which, multiplied by 2, gives the cen-
trifugal force of both mill-stones, 234 cwt.
Force of the water & cog-wheel 4.56
First trundle
Spur-wheel
Second trundles
Mill-stones
.404
- 14.6
6.554
-234.
Central force of the whole -250.118 cwt.
>>
It may be observed, that the power which
turns the wheel, or wheels, when applied in
the same manner, has always the same ratio to
the computed central force; and if a given
power produces the forces computed in this Pro-
blem, the ratio of the power to turn it round,
in any other time, is easily obtained, as follows:
PROBLEM XVI.
What power, compared with the last, would
turn the wheel in 12 seconds?
D
18
PART FIRST.
Per Theo. 10. 6:T::F:f=
FT2.
:
t2
Viz. As 122: 9²:: 250: 140 nearly, or for
every 250lb. in the first case, 140lb. will be
sufficient in the second.
Observations on the quantity of water required to
produce different velocities in the same wheel,
or train of wheels.
It has been demonstrated, (see Theo. 5 and 9%
and Art. 8.) that in the same wheel, or wheels,
the force is directly as the square of the velo-
city: viz. if a weight, suspended by a cord
coiled round the axis of a wheel, can turn that
wheel 10 times in a minute, it will require four
times as much weight to turn it 20 times in one
minute, or to communicate a double velocity.
But if the power is a given stream of water,
the case will be different.
Suppose a wheel is turned ten times in a
minute, and that every bucket receives a gallon
of water, (or any other quantity) if it is turned
20 times in a minute, a bucket can receive but
half a gallon. Hence the stream must be dou-
bled to supply every bucket with a gallon. But
they ought to receive four gallons each. There-
fore the stream, when doubled, must be mul-
tiplied by 4, or made eight times as large as at
:
ON CENTRAL FORCES.
19
first, to supply the buckets with four times the
quantity; consequently the velocity of the
wheel will be as the cube root of the quantity
of water, when it acts by gravity.
PROBLEM XVII.
If a given quantity of water turns the drum,
&c. of a cotton-mill 50 times in a minute; what
quantity will be required to turn it 40 times in
a minute?
Here the velocities are as the number of turns
made in a given time, viz. as 50 to 40, or as 5
to 4; the cubes of which are as the quantities
of water which produce them, viz. 5 × 5 × 5
=125, and 4X4X4 64. Hence, for every
125 hogsheads in the first case, 64 will be suf-
ficient in the second.
PROBLEM XVIII.
If a given quantity of water turns a wheel
six times in a minute; how often will it be
turned by double the quantity?
1
The velocities being as the cube root of the
quantities, or as 'ī: √2, viz. as 1: 1.2599:
and as one degree of velocity is to six turns,
so is 1.2599 to 7.5594 per minute, the number
of turns sought.
A
Treatise on Mills.
PART II.
TO INVESTIGATE THE VELOCITY OF A MACHINE; THE RATIO OF
THE POWER AND RESISTANCE BEING GIVEN.
PROBLEM I.
FIG. II.
LET a weight a be suspended at one end of
a cord passing over a wheel, and a weight, or
resistance, x, at the other, to determine the
space passed over in a given time.
It is evident, that a + is the quantity of
matter to be moved, and that ax is the
moving power.
ON VELOCITY.
21
EXAMPLE.
16 feet, the space
Let a 10; x = 5; s= 16 feet, the
fallen through by a heavy
body in one second;
v=the space sought.
Not taking the weight of the wheel into the
expression, we have,
80
SX
Asa+x: a—x
-x::s:
=v=the
v = the space
a + x
passed over in the first second of time by the
16 x 10-16 x 5
moving bodies, =
= 5 feet.
10+ 5
PROBLEM II.
FIG. III.
Let w and x be two bodies connected by a
cord; w hanging perpendicular, x supported
by the inclined plane; required the accelerat-
ing force, and the ratio of x to w, when the
effect is the greatest?
Put 1 radius.
s sine of the angle of elevation.
Then as the radius (1) is to (s) the sine of
the angle of elevation, so is x to sx, the force
with which the weight x endeavours to de-
scend down the plane.
22
PART SECOND.
1
And as the sum of their forces is to the
difference, so is the force of gravity to the
accelerating force.
Viz. As w+sx: w-sx:: 1 (the force of
W
SX
gravity): : the space passed over in a
wt.sx.
given time, compared with gravity, or with
the space passed over by a falling body.
The greatest effect of w will be when the mo-
mentum of x is a maximum, which will be had
by multiplying the velocity by the quantity.
Viz.
SX
W
w + sx
Xa maximum.
x
wx sx²
Or,
the momentum, and must be
w + sx
a maximum by the question; in fluxions
wx
Sǝ² = 0,
2sxx ×w + SO SX XWX
from which we get s²x² +2swx = w²; by com-
pleting the square, and extracting the root, we
have x =
W
√2
พ
EXAMPLE.
Let w 10; s.5 the natural sine of 30º,
to find x?
ON VELOCITY.
23
W
228.28, from which substract (20)
8
and we have 8.28 = x. In case of a pully,
s=1, and x = w/2-w.
PROBLEM III.
FIG. IV.
Given a weight w, suspended from a wheel
a; required the weight x, suspended from the
axis B, when the effect is a maximum?
*
AC
b
Let BC a = 1; Ac = b; s= 16 feet
the velocity of x=1; and as a : b:: 1:, and
when a = 1, the velocity of w = b, and (per
mechanics) the momentum of w will be
and that of x=a, or x, when a=1; therefore
the sum of the momentums, and as
wbx
+
wb + x: wb
wb,
x::S:
swb- ST
wb + x
v, the velo-
city of w; and as AC: BC :: b: a:: the velocity
of w: the velocity of x =
swb 8X
which mul-
wb²+bx'
swbx
8x2
wb²+bx
tiplied by x gives its momentum,
which must be a maximum.
In fluxions, bwx - 2xx × wb + bx — bx ×
wbx-xo, and b'w²- bwx- 2x²= bwx
x²; from which we find x = bw × √2−
24
PART SECOND.
1
bw: viz. if bw is multiplied by the square root
of 2 (1.414214) and be taken from the product,
the remainder is x; or if 1 is taken from the
square root of 2, and the remainder (.414214)
is multiplied by bw, the product is x.
NOTE. Whether we multiply the velocity
of w, or the velocity of x, by x, to obtain the
momentum, the value of x will be the same.
Otherwise, Letv
As a v:: b:
a:
when a = 1, and
bv
a
b
=
the velocity of x, then
the velocity of w = bv
the power which applied
is the accele-
at B will balance x, hence
bw
x
b
rating force =ƒ; and vx +1+ƒ × bv = the
b
bw-x
sum of the momentums = ƒ=bw—*, viz. 2xv
+bfv =
bw
b
x
; and by substituting
for f, we have vx + bwv =
bw-x
· b²w + bx
; the same as before.
bw
b
bw
and v =
b
Again, the same notation remaining, the
power which balances x, and
a²x
ах
b
bw
-the acce-
b
lerating force at x, and+w the whole
resistance reduced to B, by which divide
bw 20
b
ON VELOCITY.
25
and we have
b²w—bax
b²w+a²x
for the force at B, which
multiplied by x, gives
¤,
b²wx---bax²
b²w+a²x
for the mo-
mentum.
The fluxion of which is b'wx
2
2baxx X
b³w + a³x—a³xx b'wx-baxo and x=
bw b² + ba
bzw.
b2w
a²
; or if a=1, x = bw/b² +6
Mathematicians in general have estimated the
forces of moving bodies by multiplying the
quantity into the velocity, as in the first and
second solutions of this Problem. The last so-
lution is on different principles, except in find-
ing the momentum, where the accelerating
force is multiplied by the quantity; and though
it gives the value of r exactly the same when a
and bare equal, yet it varies a little when they
are unequal. And the effect of w, although
a maximum, will vary with the ratio of a: b:
for instance, if w = 10, a = 1, b = 2, the
momentum of r will be 2.0204; but if b=10,
the effect will be 2.382, and if b≈100, a will
be found 498, and its momentum 2:487.
Ꮖ
If any three of the four terms a, b, w, x, be
given, the fourth may be found, when the ef-
fect is the greatest, by the following Theorems:
E
26
PART SECOND.
Let n =√2-1 = .414214.
Then. Theo. 1. x=
bwn
a
ax
Theo. 2. w=
bnⓇ
bwn
Theo. 3. α=
ax
Theo. 4. b
wn
The two following Theorems give the ve
locities, whether the effect be a maximum or
otherwise.
wbxa
Theo. 5. v=
= velocity of w.
wb + xa
i
wb - x
Theo. 6. v=
X
velocity of r.
wb + x
b
If the velocities thus found be multiplied by
16, the product is the number of feet passed
over in the first second.
PROBLEM IV.
Given a, b, and w, to find x?
Let a 2; b= 3; w 10. Then,
(Theo. 1.) x =
bwn
a
3 × 10 × .4142
=6.21321.
2
ON VELOCITY.
27
G.
PROBLEM V.
Given, b, and a to find w?
Let a 10; b = 12; and x = 20.
(Theo. 2.) w =
ax
200
=
bn 4.9705
=40.23.
PROBLEM VI.
Given a = 1, x=100, w = 20; required
b, the distance of w?
(Theo. 4.) b=
ах
wn
100
12.071.
8.2842
PROBLEM VII.
Given w 100, b=10, x=500; required
a, the distance of x?
bwn
(Theo. 3.) a =
=.82842.
PROBLEM VIII.
The same terms given, to find the velocity
of w?
(Theo. 5.) v =
wb - ax
wb + ax
=
1000-414.21
1000+ 414.21
585.89
= .414 × 166.6274 feet the first
1414.21
second.
28
PART SECOND.
In the following Table, the power w remains
the same; the weight x varies with the distance
of w, and is found by the foregoing Theorems
and the same power in every example produces
the same momentum, viz. the weight a, mul-
tiplied by its velocity, gives 27.4516, which it
can never exceed.
TABLE I.

No.
=
X
b w
1 1 4.142 1 10
Velocity of Momentum of x.
6.6274
27.4516+
2345 O
1 8.284 2 10
3.3137
27.4516
1.12.426
3 10
2.2091
27.4516
1 16.568
4 10
1.6568
27.4516
1 41.42 10 10
.6627
27.4516
6
1 82.84 20 10
.3313
27.4516
For if the distance of w is increased, the
momentum of a will be diminished.
wb — x
For example, let a, x, and w be the same as
in No. 1 of the Table, and let b2; then v
= 10.5088, which divided by b, gives
5.2544, the velocity of x, which multiplied by
z, gives the momentum,-21.7637, but in the
Table it is 27.45.
wb + x
Let a, b, and a be varied as in Table II.
while the power w remains the same; the true
momentum, computed from the given term, is
always less than the maximum, except No. 2.1
ON VELOCITY.
29
No. a
I
b
W
12345
1
10 2
1
10 2.4142
TABLE II.

Velocity
of x.
102.666
Momen- Velocity
tum of x. of w.
26.66 5.333
10 2.74516 27.4516 6.627
3 1
10 4
10 2.4
24
9.6
1
10 50
10
.30744 3.0744|15.372
5
1 10 1000
10
.01596
.1596 15.96
6 0
0 10
10 .0000
.000 16
The greatest space that w can possibly pass
over in the first second is 16 feet; but if it has
any resistance to overcome, it must fall short of
that space, and that more or less as the circum-
stances may be and if the resistance of the
machine is not taken into consideration, the
effect is a maximum, or the greatest, when the
momentum of the power is to the momentum
of the weight as 10 to 4.14214; or as 70 to
29, nearly.
In the above Problems, the accelerating force
compared with gravity, always is as the differ-
ence of the weights to their sum, or as the
difference divided by the sum.
But if the moving power, or force, acted ac-
cording to any different law, the ratio of the
power to the weight, in case of a maximum,
would vary also. As for instance, where a
30
PART SECOND.
!
wheel is impelled by the force of a given stream,
and which force varies with the velocity of the
wheel, viz. it is always as the square of the
velocity with which it strikes the wheel, as
demonstrated in the next Problem.
PROBLEM IX.
Suppose the power to be the impulse of a
stream of water upon the floats of a wheel.
Let the quantity of water be represented by
1, and the velocity by 1, these multiplied to-
gether give the momentum; let the velocity
be doubled, and it follows that the quantity
will be doubled, for while the aperture remains
the same, a double velocity must discharge a
double quantity: hence, the momentum will
always be as the square of the velocity.
Let v velocity of the stream.
x = velocity of the wheel.
X
V-
=
va velocity with which the stream
stikes the wheel.
And v― will be the force with which the
stream impels the wheel; this multiplied by
the velocity of the wheel, gives the momentum
thereof; and when the effect is greatest it must
be a maximum; hence, v- · x² × x = м, a
maximura.
M,
ON VELOCITY.
31
.
And v³x— 4vææ + 3x²x = 0.
4vxx
; from which we get x=3.
4vx
3
=
3
And as v': v
x
: 1 1:
9: 4.
D2
EXAMPLE.
Let v6; then a 2; and v 4.
x =
And as v² (36) : : v—a' (16) : : 1 : 3.
9
Hence it appears, that when the velocity of
a wheel, which is driven by impulse only, is
one-third the velocity of the stream, the effect
is the greatest, and the power is to the resis-
tance as 9 to 4.
In the above process the weight of the wheel
is not considered; hence, the force acting upon
it may be considered as the weight, which mul-
tiplied by the velocity, gives the relative effect,
or momentum; and the conclusion is the same
as if w had been taken to represent a weight,
which, suspended from the wheel, would ba-
lance the impulse of the water.
In order to estimate the force of a stream
upon an undershot wheel, it has been common
to take the area of the section, and depth; but
this method is exceedingly erroneous, (as will
32
PART SECOND.
appear in the third part of this work) and per-
haps we cannot, from any known principles,
independent of experiments, compute the true
force of a striking fluid; we must therefore
proceed with the relative force, which is as
the square of the velocity, while the aperture
remains the same; but if the depth remains
the same, and the aperture varies, the force is
directly as the area of the aperture.
In this Problem the effect produced is as
V xx; let v 6, ∞ = 1,
= x
Then v―xx
25.
The rela-
≈ 2. Then v
xx 32.
tive effects of
3. Then v-
ææ
xx
27.
the different
≈ = 4. Then v —ax
16.
velocities of
5. Then v
x² x =
x²x
5.the wheel.
PROBLEM X.
FIG. V.
Given a lever equally thick, to find the
length, PB, so that it may, by its own weight,
just balance the end AP, and weight w?
Let z = AP.
x= PB, the length sought.
Ꮖ
m = the weight of one foot in length of the
lever.
ON VELOCITY.
33
Then, zm the weight of AP; and xm =
the weight of PB: but by the question, the mo-
mentum of PB must be equal to the momentum
of AP + W.
The momentum of PB is mxx, that is, the
weight multiplied by the fluxion of the length;
in like manner, the momentum of AP is mzz,
and the momentum of w is wz: hence, mxx
= mzz + wZ.
The fluent of which is
mx²
mz2
2
2
+wz; and
2wz
x² = x² +
; and x = √√2² +
2wz
M
M
Otherwise, without fluxions, let x = PB, the
length sought, as before, and make PC AP
CB
=z; and PD = (—+PC)
mx²————mz²
2
2
x+z
2
the distance
of the centre of gravity of CB from the prop P,
which multiplied by its weight, mx—mz, gives
for the momentum, which must be
equal to zw; the momentum of AP is equal
to that of PC, and therefore not considered;
hence we have, mx² mz² = 2zw; and x =
as before.
2zw
+
9
M
Otherwise,
If the lever is supposed to move, the mean
F
34
PART SECOND.
i
x
velocity of the end PB will be as; that of AP
Z
א
as; and that of w as z; and the quantities of
matter are w, mz, and mx, which multiplied by
their velocities, gives uz+
mz2 mx2
from which
2
2
x is found =
2wz
m
+z2', as before.
From which we have the following Theorems.
Theo. 2. z√ x² +
“
w2
W
m
m
mx2
mz
Theo. 3. w =
22
2
2wz
Theo. 4. m =
EXAMPLE.
=
Let z 2 feet, w 24lb., m = 3lb.; re-
quired x, the length which will balance the
shorter end, and weight w?
Qwz
96
Theo. 1. =
+22
+=² =
+4= 6.
= 6.
m
3
PROBLEM XI.
Given one end of a straight bar or lever,
equally thick, and homogeneous, 6 feet; the
weight of a foot in length, 4 pounds; and a
ON VELOCITY.
35
weight of 60 pounds suspended from the short-
er; required the length of the shorter, when
it, together with the weight, will balance the
longer?
Here, x 6, w = 60, m = 4, to find z.
=
(Per Theo. 2.) ≈ =
va
w²
W
+ m²
m
√36 +
3600 60
16
4
1.15 feet, the distance of
the weight from the prop.
PROBLEM XII.
Given the longer end 10 feet, the shorter 2
feet, the weight at the shorter end 100 pounds;
required the weight of the lever, so that the
whole may be in equilibrio?
x = 10 feet, z= 2 feet, w = 100lb.; re-
quired m?
This is solved by Theo. 4, where m =
4.00
2wz
=-96
which multiplied by 12, the whole length, gives
50 pounds for the whole weight of the lever.
= 4.166 pounds, the weight of 1 foot,
PROBLEM XIII.
FIG. VI.
If a power P, at the distance AC, raises a
36
PART SECOND.
weight w, at the distance DC, through DG, in a
given time; what weight м must be placed at
the distance BC, so that p may descend equally
fast, or that the angular velocity may be the
same?
Let CB CA = a; CD = b.
According to the laws of motion, a given
power in a given time moves w through DG;
wb
but when a weight is applied at B, it is acted
a
upon by a power (from the property of the lever)
which is to that acting at D as b: a; and as a :
bw
b: :w: hence the power and weight have
a
still the same ratio; of consequence the power
would urge the weight through the same space
in the same time; but the space ought to be
directly as the distance when p moves equally
fast, or when the angular velocity is the same;
and the power being the same, the mass must
be increased in the same inverse ratio as the ve-
liv b²w
locity is diminished, or as b: a ::
a
a²
the weight which applied at B, would be raised
through BE by the power P, while w would
be raised through DG by the same power; from
which is derived the third solution to the third
Problem.
ON VELOCITY.
37
Otherwise,
Let v velocity of the point D.
b
Then, Asb: a :: v=the velocity of the
point B ; but the power is able to communicate
bw
to when placed at B, a velocity v. There-
a
fore the effect produced is
vbw
мva² = vwb³, and м =
wb2
a² 9
a
Va
= M X
MX ; or
as before.
b
The same solution is obtained by a different
process, in Prob. XIII. part first, where D and
d = the distances a and b ; and there As D²:
d': F to f: and if w, we have a²: b³ as
d²
W:
b2w
a²
PROBLEM XIV.
FIG. VII.
Given the weight of a wheel a b, condensed
in the circumference; and a weight p suspended
by a cord coiled round the wheel; to determine
the velocity of the weight, and of consequence
of the circumference of the wheel?
Put w the weight of the wheel
20.
p = 1. Then, it is evident, the mass
to be moved will be w + p = 21; and as the
wheel is at liberty to rest in any position, the
moving power is only p.
38
PART SECOND.
›
Therefore, as w+p: p so is the whole force
of gravity to that part which is exerted in mov-
ing the wheel: viz. As w+p:p :: 1 :
1
P.
w + p
;
or As 21: 1:: 1: 21, which multiplied by 16,
gives the feet passed over in the first second =
16
21
= .7619 feet, or 9.14 inches.
EXAMPLE II.
Let p = 2; then w+p
lerating force will be 2 =
22, and the acce-
or 1.4545 feet the
22
11
first second.
:
EXAMPLE III.
If p=3; then w+p 23, and
X 16 2.087 feet.
EXAMPLE IV.
p
3
w+p
23
P
Ifp = 4; then = which multiplied
w+p 24
by 16, gives 2.66 feet.
In these examples, the mass to be moved is
increased by increasing the power, as it makes
part of the mass: but in computing central
forces, as in the first part of this work, the
moving power or force is considered as distinct
from the mass moved, which, according to this
ON VELOCITY.
39
Problem, may be illustrated by supposing the
mass to diminish as the power increases.
EXAMPLE V.
Let the weight of the wheel be 31, and the
1
power 1. Then _P =2, which multiplied
by 16, gives
16
32
w+P 32'
=foot for the space passed
over in the first second.
EXAMPLE VI.
Let the weight be 30; the power 2. Then
2
P
1
=
or 1 foot in the first second.
w+P 32 16'
EXAMPLE VII.
Make the weight 29; the power 3. And we
have P =
w + P
3
32
1.5 feet the first second.
Ρ
EXAMPLE VIII.
Let the weight be 28; the power 4. And
4
= = = 2 feet per second.
w+P 32
8
EXAMPLE IX.
In the four last Examples, required the time
in which the power will descend through 20
feet?
40
PART SECOND.
In falling bodies, as the space is to the square
of the time, so is any other space to the square
of the time in which it is described.
2/1
2/
In Ex. 5. As foot: 1 :: 20 feet: 6.32´´,
which is the time required to fall through 20 feet.
4.47"
In Ex. 6. As 1 foot: 1" :: 20 feet: 4.47
In Ex. 7. As 14 feet: 12:: 20 feet: 3.65.
1½
In Ex. 8. As 2 feet: 12:: 20 feet: 3.16³·
In Examples 5th, 6th, 7th, and 8th, the moy-
ing powers are as 1, 2, 3, and 4, and the
spaces
passed over in a given time are as 1, 2, 3, and 4;
but the times in which a given space is described
are inversely as the square roots of the impel-
ling powers, viz. in this case, as 1, 1.414, 1.73,
and 2, inversely, which numbers are the square
roots of the impelling powers. And it may be
observed, that when the velocity of a revolving
body is said to be as the square root of the im-
pelling power, that power is supposed to de-
scend through a given space, which is always
the case with water applied to turn a wheel.
PROBLEM XV.
FIG. VIII.
Given the power, and distance from the axis
at which it is applied, and also the diameter
ON VELOCITY.
41
and weight of the wheel, to determine the ve
locity of the power, and of the circumference
of the wheel?
Let the distance at which the power acts
bed; the radius of the wheel =r; its weight
=w.
dp -
go
Then, from the property of the lever,
the force with which p acts upon the wheel, or
it expresses the moving power.
moved is w+dp by which divide
have
dpr
r²w+d²p
до
The mass
dp and we
"
for the accelerating force at the
circumference of the wheel.
dpr
d²pr
And as r: d::
which di-
:
r²w+d²p' r³w+d²pr'
vided by r, gives
+ d²p
d'p for the velocity of p.
EXAMPLE I.
Let p = 4; d= 3; r = 9; w = 48.
108
=
3 x 4 x 9
81 × 48 +9 × 4 3924
48
109
Then, r³w+d³p
dpr
=
3
of gravity, which multiplied by 16, gives-
109
48 16
And as 9:3::
109 * 109'
the space passed
of a foot the first second.
over by p in the same time.
C
42
.PART SECOND.
EXAMPLE II.
Again, let r 18, the rest as before. And
we have
216
15588
6
433
for the velocity of the
·
wheel, which multiplied by 16, gives the feet
passed over in the first second.
In this Example, the power p, reduced to the
wheel, does not afford so much resistance as in
4
d2p 1
the first; for there? =; but here ?
9
дог
ği
*
hence if w, in this Example, had been increased
by, the accelerating force would have been
exactly half of what it is found in the first Ex-
1
ample: but without that addition it differs 8266'
or is so much above one-half of the other.
EXAMPLE III.
Let the distance d= 1; the radius of the
wheel r 84; the weight w = 9; p= 8; re-
quired the time in which p descends through
24 feet?
dpr
84
jr² w + d²p 7939'
which multiplied by 16,
gives .16929 feet the first second.
And as rd::.16929: .002015, the feet
passed over by p in the same time.
And as .002015 feet: 1": : 24 feet: 109.1
the time required.
บ
43
{
On the Centre of Gyration.
PROBLEM XVI.
FIG. IX.
Given a straight bar AB, equally thick, &c.
to find o, the centre of gyration, which if struck
will communicate the same angular velocity to
the bar as if the whole bar was collected in
that point?
The force of any particle revolving round a
centre is as that particle multiplied by the square
of its velocity, or of its distance from the centre
of motion; of consequence, the force required
to destroy that motion must be equal to it.
Put AC; BC = x; cо =y, the centre
of gyration sought.
Then z multiplied by the square of its dis-
83
tance z = z³%, and its fluent the force of
3
20
3
3
the end ac, and will be the force of the end
BC; but when x and z are removed to o, their
force will be a +z × y²; which force must be
x
3
equal to +2: viz. x+zxy'
x+z×y² =
y=
3
3x+3z
3
3
x03 +23
; and
44
PART SECOND.
{
EXAMPLE.
Let z = 7; x = 14.
3087 and
"
63
2744+343
Then, y 42+21
y = √ 49=7, the distance of the
✔49
centre of gyration from the centre of motion.
PROBLEM XVII.
FIG. X.
Given three bodies A, B, and D, connected
by a line supposed without weight, to find the
distance of N the centre of gyration, from c
the centre of motion?
Let CA a; CB = b; CD=d; CN y.
sa² + Bb² + Dď = A + B + D × y³; for
Aa Ᏼb ᎠᎴ
Bb 2
+ +
Dd2
y2 y² y2
the sum of all the forces
reduced to N, which, by the Problem, must be
equal to all the bodies placed at N and multi-
2
plied by an²; hence y
y =
An²+Bb²+Dd2
A+B+D
EXAMPLE.
Let A 2; a= 10; B = 4; b= 6; D=
=
6; d= 4.
Then,
1

200+144+96
= 6.05y,
6.05 = y, the dis-
2+4+6
tance sought.
ON THE CENTRE OF GYRATION. 45
PROBLEM XVIII.
FIG. XI.
Given the length and weight of a bar, two
weights A and B placed at the ends, and c the
centre of motion, to find N the centre of gy-
ration?
Ż
Let b = the weight of AC; a the weight
of BC; x = AC; ż = BC; w = the weight at
A; p= the weight at B.
b x 2
az
Then, wx+ + p²² + ª²²
3
3
the force
of the whole revolving round c, to which
2
w + p + a + bx CN must be equal; hence,
3wx² + bx² + 3pz² +az²

CN, or y, =
3xw+p+a+b
EXAMPLE.
Let BC = α = 1; ac = b = 2; the weight
at A =w=1; the weight at в = p = 1;
x = 14; z = 7.
X
B
=
588+ 392 + 147 +49
3x1+1+1+2
8.85, at which distance, if the whole
And we have
y=
1176
15
mass in the system was collected, it would re-
quire the same force to give it the same angular
motion, or to destroy the motion, as if the
bodies had been fixed as in the Problem.
- 46
PART SECOND.
On the Centre of Gravity.
THIS centre, in any body or system of
bodies, if sustained, the whole remains at rest.
This has been treated on by so many authors,
and is in general so well understood, that a
few observations will be sufficient.
PROBLEM XIX.
FIG. XII.
Given two bodies A and B, connected by the
line AB, to find c, their common centre of
gravity?
Let AB = a; ac = x.
:
= B
Ba
and Ax + B≈
вa: hence, x =
A+B
Then, A XвX α-x, or дx—вⱭ—вx;
EXAMPLE.
=
Let AB a = 100; A40; B 10.
±
100 X 10
Then,
20, the distance of
40+ 10
the centre of gravity from the larger body.
ON THE CENTRE OF GRAVITY.
47
PROBLEM XX.
Given the length of an homogeneous beam,
the weight of a foot in length, and a weight
suspended from one end, to find the centre of
gravity?
Let n
the length in feet.
m = the weight of a foot in length.
w = the weight suspended.
x = the longer end.
z = n-
the shorter end — n— x.
Then mzz + wz the momentum of the
shorter end; and mxx = the momentum of the
longer end. And by making their fluents equal,
mx?
according to the Problem, we have 2
mz2
2
+wz, and by substituting n-x for z, we have
mx2
¸mn²—2mnx +mx²
2
2
+ wn-wx, from which
x is found =
mn+2w
n
X
mn + w
2
EXAMPLE.
Let n = 20; m = 100; w = 1000.
Then we have x =
2000-2000
X
2000+ 1000
20/20
or 13.
= 13%,
48
PART SECOND.
1
1
PROBLEM XXI.
FIG. XIII.
Given the length of a beam AB = 2n; the
weight of a foot in length =m; the weight w,
and its distance from A = a; the weight P, and
its distance from Bb, to find G, the centre
of gravity of the whole?
Let x AG; 2 = BG = 2n
=
X.
Then the momentum of w will be-w Xx—α,
mx²
the momentum of the end x will be =
2
the momentum of P = p × z—b, and that of
z, or its equal 2n-x, =
hence we have mx² + 2wx
4mn2 4mnx + mx²
2
2wa = 4mn²
4mnx+mx² + 4pn 2px-2bp; from which
2mn²+2pn+wa bp
2mn+w+p
we find x =
If the weights w and p are at the ends of the
beam, then will x and 2n-x their distances
from the centre of gravity, and the theorem will
4mn²+4pn
mn+p
4mn+2w+2p 2mn+w+P
be x =
X 2n.
EXAMPLE.
=
n = 10; m = 4; w = 10; p= 3; a = 4;
b = 1.
Then x=
1600+120+80-6
160+20+6
=9.6451,
the distance of the centre of gravity from the
end A.
49
Of the Centre of Percussion.
As in bodies at rest the whole weight may
be considered as collected in the centre of gra-
vity, so in bodies in motion the whole force
may be considered as concentrated in the cen-
tre of percussion, or centre of force.
PROBLEM XXII.
FIG. XIV.
In a straight rod oa, required c, the centre
of percussion?
Put a oa, the length of the rod; x=oc,
the distance of the centre of percussion from
the point of suspension; oc= the distance of
the centre of gravity. And the weight of
the rod multiplied by the distance of the cen-
tre of gravity from the point o, will be equal
to the force of the rod divided by the distance
of the centre of percussion from o.
Therefore, —=—, and 3a’x = 2a', which
2 3x'
divide by a³, and we have 3x=2a, or x=
24
3
And as the stroke is the same as if the whole
weight of the rod was condensed in this point,
H
50
PART SECOND.
it is also the centre of oscillation; for, if it be
considered as a pendulum, the whole force of
the rod is exerted in the point c, to move the
pendulum, and of consequence the time of
vibration must be the same as if the whole
weight was actually collected in that point.
PROBLEM XXIII.
FIG. XV.
Let the centre of motion, or point of sus-
pension, be at a distance from the end of the
rod, to find the centre of percussion?
Let OBα=8; oa=b= 4; oc = x.
a-b
Then, “—” – og, the distance of the centre
2
of gravity from o, which multiplied by the
weight a+b, gives
a² b2 as b³
2
3x
; and 3x ×
a² — b² = 2 × a³ + b³, or x
a³ + b³
=
X
23
a² = b²
8; hence, in this Example, c coincides with B.
PROBLEM XXIV.
FIG. XVI.
Given the length and weight of a rod, and
the weight of a ball at the end, to find the
centre of percussion, or oscillation?
ON THE CENTRE OF PERCUSSION.
51
Put n = the length of the rod; m = the
weight of a foot; w the weight of the ball;
y=OG, the distance of the centre of gravity
from o; x=oc, the distance of the centre of
oscillation.
mn+2w n
mn + w
Then, y =
×2; (see Prob. XX.)
which multiplied by the weight mn+w, gives
mn²+2wn mn³+3wn²
; and x =
2
3x
mn³+3wn²
mn²+2wn
X
Otherwise,
The weight of the rod is mn,
plied by half its length, gives
which multi-
mn²
2
for the mo-
ment of the rod; and n x w is the moment of
the ball. Also, mn, the weight of the rod,
multiplied by the square of the length, n²,
gives mn, which divided by 3, gives the whole
force of the rod. And wxn' is the force of
the ball; and the sum of their forces divided
by the sum of their moments, gives the distance
of the centre of percussion from the point of
:}mn³ + wn²
suspension,
3
{mn²+wn
the same as above.
PROBLEM XXV.
FIG. XVII.
!
Given the length and weight of a rod, and
52
PART SECOND.
the weights and places of two balls fixed to it;
required the centre of percussion, or oscillation?
Put m the weight of a foot; n=the length
ow; α = OP; x = OC.
Then the momentum of the rod; that
mn² 2
2
of the weight p is ap; and that of w = nw :
the sum of the whole is
mn2
2
+ ap + nw.
The force of the rod is ; the force of the
mn³
3
weight P is PXa; the force of the weight w
mn³
3
is w Xn²; and the sum is + Pa² + wn²,
which divided by the sum of the momentum,
mn³ + 3ºа² + 3wn?
mn² + 2ºa + 2wn
gives x-
2
× 3, the same as if
mn + w + P, the whole weight of the rod and
mn² + 2nw+2ap
balls, were multiplied by 2mn + 2w + 2P'
the
distance of the centre of gravity from the
point of suspension.
NOTE.-If the distance of the centre of os-
cillation from the centre of the system, or point
of suspension, be multiplied by the distance of
the centre of gravity from the same point, the
square root of the product will be the distance
of the centre of gyration: for instance,
ON THE CENTRE OF PERCUSSION.
53
3
210 2109
mn³ + 3pa² + 3wn²
mn² + 2ºɑ +2wn
mn³ + 3Pa² + 3wn²
X
x 2
2mn + 2r + 2w
3
X
mn² + 2pa + 2nw
2mn + 2P + 2w
mn³ + 3Pa² + 3wn²
3 + w +P + mn
which last expression is the square of the cen-
tre of gyration, as found by Problem XVIII.
EXAMPLE.
Let n = 12 =ow, w = 2; a = 6 = op,
P = 2; m = 1.
Then
mņ² + 2Pa+2wn
2mn + 2P + 2w
216
6.75, the dis-
32
tance of the centre of gravity from the point o.
And men² + Spa²+3wn² x 2 = 5616
=83, the dis-
mn²+2Pa+2wn 3 648
tance of the centre of oscillation or percussion.
mn³ + 3Pa² + 3wn² 2808
Also,
= 58.5, the
4.8
3 × w + e + mn
square root of which is 7.6485, the centre of
gyration.
11
Put c64, the centre of gravity.
P = 83, the centre of percussion.
c= 7.6485, the centre of gyration.
Then GP cc, and As G: c :: G: P =
C
= 83; and P: C : : G ; G =
58.5
6.75
351
= 62.
52
G
c²
58.5
&#
1
54
PART SECOND.
PROBLEM XXVI.
FIG. XVIII.
Given the length and weight of a rod, the
centre of suspension s, a weight w at the bot-
tom, and another P at the top, to find the
centre of percussion?
Let m
the weight of a foot in length;
n = sw feet; asp feet.
Then, the whole force of the rod and balls
mn³ + 3wn² + ma³ + 3Pa².
will be
: the momentum
3
of the end sw will be
mn²
2
ma²
2
wn: the momentum
of the end PS will be +ap. And by divid
ing the sum of their forces by the difference of
mn³ +3wn²+ma³ + 3ºa²
mn² + 2wn—ma²—2ºa
their momentums, we have
X × = the centre of percussion sought.
+
EXAMPLE.
Let m = 16; wP39 dwts.; a foot;
n =
a=}
foot. Then, from the above Theorem,
2 1899
9 X x 3 =
128
27
+
468
16
9
27
+=+
117
64
156
16
78
3
846
2
X x = 1.4964
feet, the distance of the centre of percussion or
oscillation from the point of suspension. c,
the centre of percussion, is, in this case, fur-
ON THE CENTRE OF PERCUSSION.
55
ther removed from the point of suspension
than the weight w.
NOTE.-If s is the centre of the rod, or if
SB sw, and a the distance of P, the ex-
pression for the centre of oscillation will be a
2mn³ + 3wn² + 3pa³
little shorter, viz. =
2wn 2pa
o im
2
X
3
Let every thing be the same as in the last
Example, only SB Swn. Then, from
the last Theorem, the distance of the centre of
oscillation from s is found = 22.917 inches.
wn² + Pa²
NOTE 2.—If the weight of the rod is not con-
sidered, the Theorem becomes
the distance of the centre of oscillation from s.
wn
Ра
= SC,
NOTE 3.—If m = the weight of an inch,
and the distances are given in inches, we have
the answer in inches.
PROBLEM XXVII.
Given a straight bar, equally heavy, to deter-
mine the point of suspension, when the vibra-
tions are performed in the least time possible;
or when the distance of the centre of oscilla-
tion from the axes of motion is a minimum?
Let n the whole length of the bar; x =
the length of the shorter end.
56
PART SECOND.
n³-3n²x + 3nx²
Then will
n?
2nx
X
× express the dis-
tance of the centre of oscillation from the point
of suspension, which is to be a minimum.
Its fluxion is 6nxx-3n' x × n²
2
=
-2nx—2nx
× n³ — 3n² x + 3nx² = 0. And 6nx-3n² —
12x²+6nx 6nx2n²-6x²; from which
we get 6nx 6x²= n²; and by completing
the square, we have x-nx +
n²
4
||
n² n²
4
6
n
1
and x =
2
n ✓ 12°
EXAMPLE.
Let the length of the rod be 40 inches =n.
Then
40
2
408.4532x, the distance
12
of the centre of suspension from the end, when
it vibrates in the least time possible.
The centre of oscillation will be found =
23.0926 inches, equally distant from the lower
end of the rod as the centre of suspension is
from the top thereof. Hence, if the centre of
oscillation is made the centre of motion, the
centre of motion becomes the centre of oscilla-
tion, and the time of vibration remains the same.
In a straight rod, the centre of oscillation is
two-thirds of its length from the top, when it
!
ON THE CENTRE OF PERCUSSION.
57
is suspended at the top; but if the bar is sus-
pended at one-third of its length from the end,
the centre of oscillation is at the bottom, or
lower end, and the vibrations are performed in
the same time. The centre found in this Pro-
blem would be the centre of gyration, if the
centre of gravity were the centre of suspension.
In this case, the centre of gravity is in the
middle of the rod; and the centre of gyration
is n√1, which taken from 2 gives the centre
of suspension, as before.
12
When a pendulum, or vibrating body, is
placed in a horizontal position, the initial ve-
locity of the centre of oscillation is the same as
that produced by the action of gravity on bodies
left to fall in straight lines towards the earth.
Let AB (FIG. XIX.) be a pendulum, s the
centre of motion, в the centre of oscillation,
then the end в will begin to descend equally
fast as a body unconnected with the pendulum.
For, if the end As affords resistance, it throws
the centre of oscillation to в, which if As were
removed would be at c. The point c would,
in that case, begin to move with the velocity of
a falling body, and в would move faster, as it is
further from the centre of motion. Or if the
B
I
58
PART SECOND.
centre of oscillation were removed beyond the
end of the vibrating body, (see Fig. XVIII.) the
weight w would descend with a less velocity,
SW
or it would be As sc: sw:: 16: 16 × SC
the initial velocity of w. Hence, in any sys-
tem, having found the centres of gravity and
oscillation, we find their tendency to motion,
or the initial accelerating force.
PROBLEM XXVIII.
=
Given the length of a beam, 20 feet; its
weight, 2001b; a weight, w, = 60lb. at one
end; and a power P, 100, at the other end;
it is required to assign the velocity of P, which
is equal to that of w when the beam, equally
thick, is suspended by the centre of gravity?
A given power applied to any part of the
beam will communicate the same velocity as if
the whole mass was collected in the centre of
gyration.
Let a
10 feet, half the length of the beam.
'10
m = 100lb. half the weight of the beam.
The centre of gyration in the beam itself,
without the weight w and r, is
= a√. (See Prob. XVI.)
2a3
=
са
ON THE CENTRE OF PERCUSSION.
59
✓ = .57735, which × 10 = 5.7735, the
distance of the centre of gyration from the
centre of the beam.
Therefore, whether the whole mass is dis-
persed equally through a beam 20 feet long,
whether it is collected in the centre of gyration,
or whether it is diffused through a circle, the
radius of which is 5.7735 feet-yet a given
power, applied at a given distance, would, in
the same time, communicate the same angular
velocity, or would turn it equally fast round
its axis.
Next, the resistance of the beam must be re-
duced to the extremity of the arm, where the
power acts, (see Prob. XIII.) which is done by
multiplying the weight by the square of the
distance of the centre of gyration, and dividing
by the square of the distance of the power P
from the centre of the beam. Thus the square
of the distance of the centre of gyration is
a²
3'
2ma²
3
and the weight is 2m; their product is
which divided by a', gives 2m for the whole
3
resistance of the beam reduced to the end.
And, as 2m = the whole weight, the resistance
which it affords to a power acting at the end
is of its weight.
60
PART SECOND.
We have therefore w+P+
2m
3
the mass
=
to be moved; and 100-60 40 the mov-
ing power. And the space passed over in one
second, compared with gravity, is
100 60
100 + 60 + 66.6
P- W
P + W + 2m
3
.17647, which multiplied
by 16, gives 2.822 feet the first second.
Otherwise,
If we take 40, the moving power, from 100,
we shall have each end loaded with 60lb. The
centre of gyration of the beam thus loaded will
be expressed by
2wa² + 2ma™
3
✓ 58.33: the
2w+2m
mass is 2w+2m, which multiplied by-
2ma²
3
•2wa²+2ma²
3
2w + 2m
gives 2wa' + which divided by a², the
2m
distance of the power, quotes 2w + for the
3
whole resistance reduced to the end of the beam,
to which add pw, and we have the whole
mass to be moved; by which divide the moving
the quotient is the accelerating
power, P-
W,
P --- W
force,= 2w + 2m + P — W
40
120+66 +40
Otherwise,
3
40
2263-
PW
2m + P + w
3
=.17647, as before.
护
​ON THE CENTRE OF PERCUSSION.
61
If we divide the distance of the weight w
by the distance of the centre of oscillation, we
have the initial velocity.
If 2m = the whole weight of the beam; and
2a = the length, as before;
Then will
2am +3aw +3aP
3P- 3w
express the distance
of the centre of oscillation, by which divide
the distance of w, and we have
3P 3w
2m+ 3w+ 3P
.17647, the accelerating force compared with
gravity, the same as before.
PROBLEM XXIX.
Given one end of a lever 6 feet, the other
10, the weight of the whole 160lb. a weight
w=300lb. at the shorter end,
= 500lb. at the longer end;
celerating force?
Let a 6, the shorter end.
b 10, the longer end.
and a power ℗
required the ac-
m = 160, the whole weight.
Then, the square of the distance of the cen-
tre of gyration (Prob. XVI.) is
a³ + b³
38+3b
;. which
multiplied by the weight m, and divided by the
square of the distance of P, gives a + b² X
3036
m
虐
​62
PART SECOND.
the whole resistance of the lever at P. To this
add the weight w, reduced to P, and the power
P; and we have the whole resistance at P =
a³ + b³ m a²w
X +
3a+3b b2
b2
+P648.533.
Then, as 16, the whole length of the lever,
is to 160, the whole weight, so is 10, the longer
arm, to 100, its weight, which taken from 160,
leaves 60, the weight of the shorter.
2wa + 60a · 100b
26
Then (Prob. XXI.)
= 148,
which, if placed at P, would exactly balance the
weight w; this, taken from P, leaves the mov-
ing power = 352, which divide by the whole
mass, and we have 648.533) 352 (.54276,
which multiplied by 16, gives 8.684, the feet
through which p would descend in one second,
if the direction was perpendicular.
Otherwise,
Let m = the weight of a foot in length.
Then,
mb³+3rb²+ma³+3wa² × = the cen-
mb²+2pb-ma²—2wa
608
tre of oscillation = ; by which divide 10,
33
330
the distance of P, and we have = .54276;
608
and as b is to a, so is the space described by
to that described by w.
ON THE CENTRE OF PERCUSSION. 63
1
PROBLEM xxx.
Given, a 6 feet, the shorter end of a lever;
b = 10 feet, the longer end; m = the weight
of the longer end, 100lb.; the weight of the
shorter n=60; w=78; and let the power p
be suspended from the longer arm at a distance
d=7: required the accelerating force at P?
will be =
3mb+6rd-3na-6aw
The centre of oscillation (see Prob. XXV.)
2mb²+6rd²+2Pa²+6a²w
; by which di-
3mbd+6pd2-3nad-6awd
vide d, and the quotient is
2mb²+6Pd²+2Pa²+6a²w
= the accelerating force at P; .359 parts of
gravity. Or, by the process in Prob. XXVII.
if m = the weight of a foot, then 2wa+ma² —mb²
=
2d
=211, the weight which, placed at P, would
balance w: hence, the accelerating force, con-
sidered alone, is 500-211
mass to be moved, reduced to P, =
a²w
288. The
a³ + b³
X
3a+3bd2
m
+ aw + p = 803.129, by which divide 288+,
d2
P
and we have .359, as before.
PROBLEM XXXI.
Given, the radius of a solid wheel, equally
thick, = d = 10 inches; the radius of the axis
= b = 1 inch; a power p = 2lb. suspended
64
PART SECOND.
*
from the wheel; and a weight w 16lb. from
the axis; the weight of the wheel = 4lb. = m :
required the space descended through by the
power compared with falling bodies?
First, to find the centre of gyration in the
wheel;
Let x the distance of a particle from the
centre.
q = .7854.·
Then will 49 × 2x the circumference of a
circle or ring, the diameter of which is 2x.
The fluxion of its area will be 8qxx. And,
As 8qxx: 4qd', the whole area,
the weight
of any particle a the whole weight of the
wheel, =
Smqxx
4qd²,
distance of the particle, it gives
4aqd²
8qxx
be multiplied by x, the square of the
m; and if a, or its equal,
8 mq x³ x
2mx4
4d2
md2
2
4qd2
(and when x = d) = =y'm; and y² =
d²
or y = d√1 = the distance of the centre of
gyration from the centre of the wheel = 10 ×
.707167,0716 inches.
The weight of the wheel multiplied by the
square of the distance of the centre of gyration,
ON THE CENTRE OF PERCUSSION.
65
2
{==/ × m) and divided by the square of the
radius, gives the resistance which it affords at
the circumference=”. The weight w, reduced
to the circumference, is wb. Suppose the weight
d²
of the axis to be 5lb.=g, the resistance at its
surface will be
b2
of the wheel =
m wb2
2
Xg, and at the circumference
X
2
d2,
these added, give go
gb2 b2
2d2
+P, the whole resistance; by which
d'
the moving power, (see Prob.
+ +
2
d2
bw
divide P
XV.) and we have
P
bw
d
gb4 m wb2
+ + + P
2d2 2
d2
.4
4.1625
=.096, which multiplied by 16, gives 1.536
feet the first second.
If it is required to raise the weight w through
a given space in the least possible time, by the
action of the power P, it will be necessary to
determine the diameter of the wheel to that of
the axle. Let b the diameter of the axle,
and z that of the wheel, which is variable.
The accelerating force will be expressed by
2pz² —— 2bwz
2wb² + mz² + 2pz²⁹
= the space through which
P descends in 1 second, compared with gravity,
(1). And as the square root of that space is to
K
6.6
PART SECOND.
1 second, the time in which it is described, so
is the square root of any other space s to√x
√2wb² + m²² + 2pz², the time of describing it,
2pz2-2bwz
which time is to be a minimum, or the least
possible: its fluxion is 2mzz + 4pzz ×

2bwz
2p2*
+ 2pz² = 0.
-
4 pzz - 2bwz × 2wb² + m²²
4pb
4pbz = 2wb²; and 2²
22-
Qwb2
2p+m
n
From which we get m²² + 2pz²
X
x 2 =
2p + m

: if_4pb
2p+m
=n, then z =
Qwb2 n2
+
2p+ m
4
+= the radius of the wheel required. If
2
the weight of the wheel is not considered, the
w bw
Theorem becomes zb✔ + +
p² Ρ
P
If the power P is suspended from the axle,
and the weight from the wheel; and if the
radius of the axle be 1, that of the wheel z,
the weight of the wheel m, and its centre of
gyration y; then will
P- WZ
× 16 be
y²m + wz² + P
the space passed over by p in 1 second; which
multiplied by z, gives the space passed over by
w in the same time. Or if P is suspended from
the wheel, and w from the axle, then the space
passed over by P will be
× 16;
PZ2 WZ
y²m + w + P2
which divided by %, gives the velocity of w.
ON THE CENTRE OF PERCUSSION.
67
On the Maximum of Machines, &c. at the end of
a given time.
PROBLEM XXXII.
Given the weight of a beam 200lb. the arms
of equal lengths, a weight of 100lb. suspended
from one end; it is required to ascertain the
weight suspended from the other, so that when
it is multiplied by its velocity the product shall
be a maximum ?
Put m
200lb. the weight of the beam.
p = 100lb.
x = the weight sought.
X
Then will p—x (see Prob. XXVII.) be
m+ p + x
3
the accelerating force; and px-x² - the mo-
m+p+x
3
mentum of x, which in fluxions is px- 2xxx
+p+x-x × paxo; from which
m
3
2mx
we get x² + 2px +
3
3
the coefficients of x, 2p+ 2m
pleting the square, we find x =
一
​44.152.
pm +p²; by putting
n, and com-
3

pm
n²
3*
+p²+
68
PART SECOND.
p-x
m + p + x²
3
the
space passed over in the first
second,=.263, which multiplied by the weight
x, gives the product 11.7; which product is
greater than can be obtained by assuming x
either more or less than given by the Theorem.
But if the weight of the beam is altered, al-
though the power p remains the same, the
weight x will be found to vary. For example,
if the weight of the beam is 30, then x (from
the above Theorem) will be found 42, and
its velocity .381, which × 42, gives 16, the
momentum. So that by diminishing the weight
of the beam, the same power, in an equal time,
produces a greater effect on x; not that the
absolute effect is greater, but the additional
force which is now exerted on x was before
employed to move the beam.
Again, let the weight of the beam be 360,
p = 100 as before, and we shall find, as above,
the value of x 45.33, its velocity.206,
and their product, or the momentum, 9.337.
Therefore, when the effect is the greatest,
the weight x increases as the beam becomes
heavier; but the velocity diminishes in a greater
ratio of consequence, the effect produced by
ON THE CENTRE OF PERCUSSION.
69
the power p, in raising weights, is diminished
by increasing the weight of the machine.
PROBLEM XXXIII.
Given the length and weight of a beam, the
power suspended from the longer arm, to de-
termine the weight at the end of the shorter,
when the effect is a maximum?
Put a
n
length of the shorter = 6.
its weight=60.
b = the longer arm 10.
m= its weight=100.
p = 500.
Then will
na²
2a²w
= the
amb + 2apb
mb² + 3pb²+na² + 3a²w X 942
accelerating force at w. Let the known terms
in the numerator be put = N, and those in the
denominator =Q, and we shall have N-2aw
Q+ 3a²w
× w a maximum; in fluxions Nw— 4a²ww ×
Q+3a³w — 3a'w × Nw — 2a¹w = 0.
And w=
ON Q²
Q
9
3a²*
amb+2apb-na³N
mb² + 3pb² + na² = Q = 162160.
63840.
70
PART SECOND.
ÓN
6
=1725382400.
=2921762844.44
9
Sum 4647145244.44, the square root of this
is 68169.9, which multiplied by (=) is
36
3a
is
1893.61; from which subtract 1501.4814()
leaves 392.13 ≈w, the weight required.
The same conclusion may be brought out by
a different process. If
If ✓
13 b³
3a +36
=r, the cen-
tre of gyration in the beam; then will
m
an aw
p +
2 2b
b
the velocity of p.
m+n
a²w
× p² + p +
b²
b2
Then let +
+ P = 0.
m
an
m + n
26
N; and
b2
X r
And we have Nw the effect; which
aw²
b
a²w
2+
b²
by the Problem must be the greatest possible.
The fluxion of this expression is Nw
Qaww
b
a²w
aw
aw³
xQ+
b2
X NW
ba
b
= 0.
Whence
b Nob
w=
+
ob
Qb²
|
a
ON THE CENTRE OF PERCUSSION.
71
The value of N and Q in this process will be
different from what they are found in the last;
but the value of w will be exactly the same.
For example,
2 26
an
P+
= N = 532.
m + n
x r² + p = Q = 540,533.
b₁
Nob
a
= 479272.88.
811600.79.
Sum 1290873.67.
b
1290873.67=1136.16; which multiplied
by, gives 1893.6
Subtract 1501.4=
Rem.
Qb2
a
392.2 = w, the answer as before.
PROBLEM XXXIV.
Let the weight P be suspended from the arm,
at any distance from the end; required the
weight of w, in case of a maximum ?
Let a = the shorter arm.
b = the longer.
d the distance of P from the centre.
n = the weight of the shorter end.
m = the weight of the longer.
72
PART SECOND.
The centre of oscillation of the whole will be
2mb²+6rd²+ 2na²+6a²w
expressed by 3mb + 6rd-3na-6aw by which
divide a, the distance of the weight w, and we
3amb + 6ard 3na² 6a²w
have
2mb² + 6rd² + 2na² + 6a²w
the accelerat-
ing force, or initial velocity of w; which, when
multiplied by w, must be a maximum: its flux-
ion is ambw + 2apdw
mb² + 3pd² + na² +
ambw+2apdw
na² w
na w
2a³ ww ×
3a³w
3a²w ×
2a wo, which
multiplied and reduced, gives ɓa*w²+a*nw+
3na³w + 12a³pd³w + 4ma²b³w = am³b³ +
2apdmb²+3ambpd2+6ap³d'+a³mbn+2a'pdn
3na'pd¹— n'a'.
nma²b²
Let the coefficients of the first power of
n
2pd2 2mb2
n
+ +
+
a²
w, б
2a
3a²
= c; then by
completing the square, &c. we get w =
1 (am²b³ + 2apdmb² + 3ambpd² + 6ap³d³ + a³mbn

a²
6
+ 2a³pdn
nma2b2
3nà²pd²
n²a² C
+
C
6
4
2010
EXAMPLE.
Let a = 1, b = 5, d = 3, m = 5, n = 1,
p = 10.
First, to find the value of c, the coefficient
of w.
1
ON THE CENTRE OF PERCUSSION.
11 육
​* 10 */*
.166
n
.5
20
2pd¹
= 180,
a²
2mb³
= 83.33
3a²
Sum 264 = c.
.
73
Under the vinculum we have,
Positive Terms.
Negative Terms.
am² b³
=
3125
nma²b³
125
2apdmb² = 7500
3a'npd² = 270
3ambpd² =
6750
n²a²
1
бap❜d'
16200
a❜mbn
25
Sum 396
2a pdn =
60
Sum positive 33660
Sum negative
396
Difference 3326465544, to which
add 17424, (—) and extract the square root of
the sum, which is found
vided by a² (1),
the value of w
C
151.552; this di-
and taken from it, leaves
2
19.55, the weight required.
The above Theorem may be contracted by
putting the known quantities, or terms, in the
L
74
PART SECOND.
numerator amb +2apd—na², = N = 84; and
those in the denominator, mb + 3pd² + na²,
=Q=396. Then, by the Theorem in the
ON Q²
Q
6 9
we have the
3a²
last Problem, (v +
solution.
ele 5544
= 17424
9
their sum 22968, the square root of which÷
Q
a², or × 12, is 151.55; and = 132, which
3a2
taken from 151.55, leaves 19.55 as before, but
by a much easier process.
On the Maximum of Bodies, when the space is
given.
I have now, by various processes, by different
methods, and from different principles, demon-
strated what the greatest effect is which a given
body, acted upon by gravity, can produce in a
given time. I shall now proceed to demon-
strate what the greatest effect is which a given
body can produce, in falling through a given
space. If the ratio of w to x is such, that the
effect produced is the greatest at the end of one
second of time, it will be the greatest at the
end of any other period of time. But if the
ON THE CENTRE OF PERCUSSION.
75
space is given when the effect is greatest, the
ratio of w to x will vary, or be different to
what it was when the time was given.
PROBLEM XXXV.
It is required to determine the greatest ef-
fect that a given body can produce, in falling
through a given space?
Let w
X
the weight of the body, or power.
x = the resistance, or weight to be raised.
And let them be connected by a line passing
over a pulley. (See Fig. II.)
The accelerating force will be
w
w+x
(Prob. I.)
which multiplied by 16, gives the feet passed
over in the first second. But the time and ve-
locity are as the square root of the space, and
which multiplied
will be expressed by √/w + x
by x, gives x
W
x
w + x
which, by the Problem,
must be a maximum. Its fluxion is 2wxx-3x²x
o. From which
x × wx² — x³ = 0.
× w + x − x × wx²
we have 2x + 2wx² = 2w³x; which, divided
by 2x, gives x² + wx = w²; and x² + wx +
202
!
= w² + 22.
By extracting the root on both
sides, we get x =
w
√5
2
20
1
76
PART SECOND.
EXAMPLE.
Given w = 10; required x?
The square root of 5 = 2.236076, which
multiplied by (= 5), gives 11.18038; from
= x.
W
which subtract, and there remains 6.18038
When w= 10, this number, or value
of x, is the maximum for any space, as 4.142
is for any time.
NOTE 1.-It appears by Prob. III. the time
being given, that when the effect is greatest,
the power descends through 6.627 feet in one
second, and, of consequence, from the laws of
falling bodies, through 26.5 in two seconds,
and through 3 x 3 x 6.627 59.6 in three
seconds, &c. Therefore, the weight remaining
the same, the space through which it is raised
by a given power will be as the square of the
time.
NOTE 2.-It appears by this Problem, the
space being given, that there is a limited time
in which the power will produce the greatest
effect.
NOTE 3.-If T
any given time, the num-
ber of strokes made in that time will be
ON THE CENTRE OF PERCUSSION. 77

rw-ra, which multiplied by
sw + sx
T
= IV
sw + sx
TW ------ TX
x, gives T
for the maximum; the
sw + si
\rwx²-rx³
fluxion of which is the same as that already
found in this Problem.
Let T
EXAMPLE.
3600 seconds, or one hour.
w = 10.
x = 4.142.
r = 16.
s = 26.5.

Then
sw + sx
rw——rx
stroke; and TV
2 seconds, the time of one
1*X
sw + 8x
= 1800, the strokes in
one hour; which multiplied by 4.142, the
weight raised at one stroke, gives 7456, the
weight raised in one hour.
But if x = 6;
sw + sx
Then-r
=2.57 seconds, the time of
one stroke, by which divide 3600, and we get
1400.7, the number of strokes in one hour;
which multiplied by 6, the weight raised by
one stroke, gives 8404.2 for the whole weight
raised in one hour.
78
PART SECOND.
PROBLEM XXXVI.
Given a power w applied to the circumference
of a wheel; required the weight x suspended
from the axle, when the product arising from
the weight into the velocity is the greatest
possible at the end of a given space ୭
Put a radius of the axle.
bradius of the wheel.
s = the given space through which w
descends 25.
r = 16.
x = weight sought.
The accelerating force at w will be
And as
barw baxr
b²w + a²x
: 1″ :::
b²rw-baxr
b²w + a²x
wb² + sa²x
✓rwb² rabx

the time in which w falls through the space s;
by which divide the time T, and we have
Twb² — abrx
swb² + a²sx
in the said time.
the number of strokes made
The number of strokes, mul-
tiplied by the weight x, which is raised at one
stroke, gives T
√ abwx²— a²x³
for the maximum.
√ swb² + sa²x
2
Its fluxion is 2bwxx-3ax x x b³w + a²x—
a²x × bwx² — ɑx³ — o.
ax³ = o. From which, by mul-
tiplication and reduction, we get 2a²x²+3b’wx
2b³w²
3b³w abw
—
abwx=
;
and x² +
x x =
a
2α²
ON THE CENTRE OF PERCUSSION.
79
3b²w -- abw.
Let
2a²
=n: then by completing
b³w2
the square, &c. we get r =√ +
n
n
s in
EXAMPLE.
Let a = 1, 62, w≈ 10.
Then 12.74, and is raised 12.5 feet,
while w falls 25 feet. The time of descent is
swob² + sa²x
expressed by
and in this case is
rb’w—baxr?
2.38 seconds.
PROBLEM XXXVII.
Let the weight of the wheel be given, =m;
the centre of gyration y; a power p acting at
the circumference: required the weight w sus-
pended from the axle, when the effect of p in
raising it through a given space is the greatest
possible?
Let the radius of the axle be = 1; that of
the wheel = r.
Then will pr² —— wr
y²m + pr² + w × 16 the number
of feet which w ascends in one second.
prz
And as

201 1″::: y³m + pr² + ∞
·y²m + pr²² + w
16
?
pr
W
X
the time of ascent through the space s; by
80
PART SECOND.
2
which divide the time T, and the quotient is the
number of strokes made in that time; by which
multiply w, the weight raised at one time, and
we have the whole weight raised in any given
time T, and which by the Problem must be the
greatest possible: hence we have
for the maximum. The fluxion
2prww
3w³w × y³m + pr² +
prw² — w³
y³m+ pri² +w
of which is
w — w x
prw² - w³ = 0. From which we get w³ +
3 pr² + 3 my² — pr X w = prmy' + p²r'; and by
2
×
putting n the coefficients of w, we get w=

n²
n
√p³r³ + prmy² +
4|
2
EXAMPLE I.
Let p = 10, r = 2, y² = 2, m = 1.
3pr‍² + 3my³ — pr = n = 53; and w =
2
Then
=
800+40 + 702.25-26.5 12.77.
EXAMPLE II.
Let the weight of the wheel be 4, =m, and
y' 6, to find w?
=
n 86; and w800 + 480 +1849
-43 12.9; and the time of rising 25 feet
will be 4 seconds.
ON THE CENTRE OF PERCUSSION. 81
EXAMPLE III.
Given the weight of the wheel 10lb.; the
power p 10lb.; y² = 10: required w, and the
time of rising 25 feet?
From the above data we find n 200, and
w = √800 + 2000 + 10000 –
and the time is
5.9 seconds.
100
13.13;

my² + pr² + w
X
× √25 =
pr -- w
16
It
appears that, by increasing the weight of
the wheel, &c. the time of ascent is prolonged
near two seconds, and the weight raised is very
little more. (See Prob. XXXII.)
PROBLEM XXXVIII.
Let the power w be applied to the axle, to
raise the weight a suspended from the wheel
(the rest of the notation as in the last Problem)
through a given space; required x, when the
effect is the greatest?
w - TX
y²m + r²x + w
is the space passed over by w
compared with gravity (1); and, by the last
Problem,
wx² - rx³
y²m + w + r²x
is the greatest effect.
Its fluxion is 2wxx- 2rx²x × y*m + w +r²x
M
82
PART SECOND.
2
3
— r²x × wx
rx³ =0.
From which we find
x = √ 2w² + 2mwy²
n
+-
2r³
3rw + 3my²
g. W
NOTE.
N.
2r'
NOTE.-In constructing machines, it will,
in general, be of more importance to compute
the effect produced by a body in passing over
a given space, than at the end of a given time.
But suppose it should be required to assign
the distance at which a given power must be
applied from the axis of a wheel, so as to pro-
duce a greater number of revolutions, in falling
through a given space, than could be produced
by any different application of the said power,
in falling through the same space, in any pro-
portionable part of the time: the answer is,
apply the power as near the axis as strength in
the machine and other circumstances will admit.
(See Prob. XIV and XV.) It has been proved,
that if a body falls through a given space, sup-
pose 20 feet, in 20 seconds, and produces 100
revolutions, if applied at twice the distance
from the axis it will fall through the same space
in 10 seconds, but will only produce 50 revo-
lutions, the vis inertia of the power not con-
sidered; but if it is taken into the computation,
ON THE CENTRE OF PERCUSSION.
83
it will require more than 10 seconds to make
50 revolutions.
For example,
Let m the weight of the wheel
r
the centre of gyration
10.
31.9.
10.
p
p the power
=
x= the distance from the axis at which
X
Then
p is applied = 1.
16px²
mr² + px²
the feet fallen through by
in the first second. And as foot: 1"
:: 20 feet: 20', the time of descent. But if
x2, by the same process, the time of des-
cent will be found 10.046 seconds; and in
falling through a given space, the number of
revolutions must be inversely as the diameters.
Hence, by increasing the distance at which the
power is applied, we diminish the effect when
the space is given. But if the time was given,
the distance might be found such, that the
effect would be the greatest.
PROBLEM XXXIX.
Given the weight of a fly=m= 31.9; the
centre of gyrationr 10; the power p
r= =
=
10: required x, the distance at which p
84
PART SECOND.
must be applied, to produce, in a given time,
the greatest number of turns?
mr2
x²
-the whole resistance of the wheel re-
duced to p, to which if we add p, we have
mr2 +p the whole mass; the moving power
Ꮖ
px2
which
being divided by this, gives mr² + pa²
multiplied by 16, gives the space passed over
by p in the first second; which divided by
2x × q (2x × 3.1416) gives
px
the
2q × mr² + px²³
number of revolutions performed in that time.
The fluxion of which is px × mr² + px³-2pxx
x pxo. From which we get pmr² + p²x²
m
=2p²x²; and x = r√ = 10
p
31.9\
10
= 17.8,
which, in this case, is the distance at which the
power ought to be applied, in order to pro-
duce the greatest number of revolutions in a
given time.
PROBLEM XL.
Given the weight of a beam suspended by
the middle, m = 200lb.; and a weight p =
100, suspended from one end: required the
weight to be suspended from the other, so that
the effect may be the greatest after having
ascended through a given space?
}
ON. STEAM ENGINES.
85
It is presumed that the ends of the beam
are circular, and that the weights move in per-
pendicular directions.
The accelerating force will be
Prob. XXVII & XXXII); the
p - x
m+p+ x
3:
(see
square root of
which multiplied by x, gives the maximum =
2
m
Its fluxion is 2pxx — 3x² x × ~ ~
~ + p + x
px²x³
-+p+x°
3
x
x x
× px²-x³ = 0.
3
3
o. From which we have
x² + px + m² = pm +p². Let p+™ =n;
2
3
2
then, by completing the square, &c, we find x

Jpm
== + p² +
3
n
sia
n
4
2
ཤྭ་
On Steam Engines.
PROBLEM XLI.
IT has been demonstrated, that when the
pressure upon the steam-piston is to the weight
of the pump-rods and water as 1000 to 618,
the effect is the greatest when the piston de-
scends. And if it is so adjusted, that the weight
of the rods, &c. when in the water, be to the
weight of the steam-piston, plug frame, &c. as
1000 to 618, the engine will do the most work
86
PART SECOND.
in a given time. If the pressure of the air is
taken at 14lb. upon an inch, then as 1000: 618
::14: 8.65, the weight with which the end
over the shaft should be loaded for every square
inch of the steam-piston; (not considering the
friction of the parts, or weight of the beam,)
which would amount to 1245lb. for every square
foot of the steam-piston: but every thing con-
sidered, this is far too much, and we may, in
general, make the load from 800 to 860lb.
per foot. In large engines, the friction is less,
in proportion to their power, than in small
engines; of consequence the load may be more.
Put d = diameter of the steam-cylinder, in feet.
q= .7854.
1 = the length of the stroke, in feet.
に
​=
p the pressure per foot, in pounds avoir-
dupoise.
w=62.5lb. weight of a cubic foot of water.
h the number of feet the water is to be
raised.
c = diameter of the pump, in feet.
g6.1276, ale gallons in a cubic foot.
n = 10.28, cubic feet in a hogshead.
Then will
qd² = area of the steam-piston, in feet.
1
ON STEAM ENGINES.
87
pqd' = the weight of the water to be lifted,
in pounds avoirdupoise.
pqd¹ — cubic feet of water in the pump;
W
which divided by the height h, gives
pqd
hw
= the area of the pump-piston; which
multiplied by the length of the stroke l, gives
lpqd²
kw
cubic feet raised per stroke.
From which equations we have the following
Theorems:
who
Theo. 1. d=
P
Theo. 2. c = ✓ pd²
hw
pd¹
Theo. 3. h =
wc2°
Theo. 4. lqc
=
cubic feet per stroke.
Theo. 5. glqc
gallons per stroke.
EXAMPLE I.
Given the diameter of the steam-cylinder,
3 feet; the length of the stroke, 6 feet; the
depth of the well, 50 feet: required the dia-
meter of the pump, and the quantity of water
raised at one stroke?
88
PART SECOND.
Here we have given the diameter of the cy-
linder = 3=d; the length of the stroke=6
=1; the depth of the well 50 = h; to find
hw
3125
==
c; which, by Theo. 2, is = √/pd² = √/7515
1.55 feet. And the quantity per stroke is, by
Theo. 4, = lqc*, – 6 X .7854 X 2.404 =
11.328 cubic feet.
In the above, p is taken at 835lb. instead of
1245, which it ought to be taken at, were it not
for the various sorts of resistance, friction, &c.
which do not enter into the above computation.
·
If all cylinders were equally well bored, and
the work executed in the same manner, an esti-
mate might be made for friction, &c. which,
compared with the moving power, would al-
ways be, in the cylinder, as the circumference
to the area of the piston: or, in different en-
gines, it would be as the diameters of the cylin-
ders and pumps. To which should be added
the weight of the beam, rods, plug-frame, &c.
EXAMPLE II.
Given the diameter of the pump, 1 foot;
the height to which the water is to be raised,
240 feet; to find the diameter of the steam-
cylinder?
:
ON STEAM ENGINES.
89
Here we have w = 62.5lb.; h = 240; c =
=
1: and whqc² = pqd' the whole weight of
the cylinder of water to be lifted. From which
we find, Theo. 1, d= √✓ whe²
P
=
15000
835
17.96 = 4.23 feet, the diameter required.
EXAMPLE III.
Given the quantity' of water to be raised in
one hour, 200 hogsheads; the depth of the
water, 100 yards; length of the stroke, 6 feet;
number of strokes in a minute, 10: required
the diameter of the cylinder and pump?
200 hogsheads, the quantity raised in one
hour, is equal to 12600 gallons, which divided
by 600, the number of strokes made in the same
time, quotes 21, the gallons to be raised at one
stroke. Therefore, (Theo. 5) 21 = glqc', and
= .852 feet, or 10.22 inches, the
c =
21
glq
diameter of the pump: and (per Theo. 1) d =
whc 4.04 feet, the diameter of the cy-
p
linder.
N. B. If the weight of the pump-rods and
plug-frame be taken into the computation; let
their weight, when the weight of the steam-
piston is taken from them, be put = n pounds.
N
'
90
PART SECOND.
!
་
Then will d=
ކ
✓ hw
pd²
n
qhw
whc2
n
+
And c =
Ρ
qp
EXAMPLE IV.
Required the dimensions of an engine to
raise 250 hogsheads per hour to the altitude of
55 yards, the weight of the rods being 2000lb.?
250 × 63 15750, the gallons per hour,
which, at 12 strokes in a minute, is 22 gallons
per stroke 3.59 cubic feet = qlc', and c² =
3.59
gl
-; the square root of which is .87 feet, or
10.4 inches, the diameter of the pump. And
d = √ who²
p
the cylinder.
+
n
pq
=3.53 feet, the diameter of
PROBLEM XLII.
2u,
Given the length of an engine beam
its weightm, weight of each horse head, or
arch at the end, c, weight of the steam-piston
and chains, weight of the plug-frame and
its archu, its distance from the centret,
pressure of the atmosphere upon the piston
=p; required the weight of water lifted, or
resistance overcome, when the effect is greatest?
ON STEAM ENGINES.
91
Suppose the beam to be suspended by the
centre, and that the piston and chain are ba-
lanced by a part of the pump-rod and chain at
the other end: then will the whole weight of
the beam, arches, piston, &c. be 2c + 2s + m,
which putr, and let the centre of gyration
6ca2+ 6sa² + ma²
6×c+s+ 3 m |
in the beam be y, v
==


4c + 48
X
3
ry²
@2
2c+28+m+1, then will be the
whole resistance of the beam, &c. reduced to
the end to which the power is applied.
x
Let the resistance sought: then will
p — * × 16 be the space passed over in the first
p+ ryz
a²
second.
+x
7
Let the length of the stroke: then,
As
- x × 16
p− x
p+ry²+ x
: 1² : : 7 : 1 x
1:1 P+
ry²+x
a²
px × 16
; the
square root of which is the time of passing over
the space 7. And the greatest effect will be ex-
pressed by
px²
ryz
p+ +x
; the fluxion of which
is 2pxx — 3x²x × p+ + x − x × px²-x³
ry²
= o. From which we get a +p+
3ry2
2a2
xx=
p² + pry². Let p +
3ry²
2a2
= ng
n, the coefficients of
92
PART SECOND.
¤; and we shall have x² + nx +~-~
+2²: from which we find a =
n
2*
sp
Ꮖ
n
pry²
4
a²
+p²
pry²
a²
n
+p²+
4
- Then, to find the additional weight of
the pump-rod, so that the ascent of the piston
may be performed in the same time as the de-
scent, we have Asx:p::s: the whole
weight of the pump-rods and chain, from which
subtracts, and we have the additional weight
sought; which, if the rods be not heavy enough,
must be supplied by an equivalent weight added
to the end of the beam, and must be further
increased by reducing the plug-frame to the end
of the beam, in the following manner, viz. a²
the resistance at the end of the beam; and As
sp
x :p ::
ut² put²
xa² ›
; hence P +
a²
XC
put2
xa2
t2u
the whole
weight suspended at the pit end of the beam.
This diminished by s, and the remainder taken
sp― sx
from x, leaves x — + put = the weight
XC
xa2
of water to be lifted, not considering the
friction.
EXAMPLE I.
=
Let a 12, m = 1000, c = 280, s 700,
=
u = 200, t = 7, p = 2000: then will r =
i
#
A

ON STEAM ENGINES.
93
ry²
2960, and y² = 111.55; also ¹² = 2293; n
= 5440.
pry2
= 4586000
p²
=4000000
n²
= 7398400
4
Sum 15984400; the square root of this is
3998, from which subtract (= 2720) and
n
2
we have 1278 = x, the whole resistance, which
sp
must be diminished by s +
Ꮖ
put2
xa2
= 502:
and we have 785 for the weight of the water to
be lifted. And if 7 = 6 feet, the time of de-

Wix
scending will be (lx
ry²
P+ + x
a²
p - x × 16
1.6 se-
conds, which doubled, gives the time in which
the piston, &c. ascends and descends = 3.2
seconds, which would give 18 strokes in one
minute, if the piston made no stop at the top
or bottom.
Let a 12, m
=
EXAMPLE II.
5000, c = 1000, s 2000,
=
u = 500, t = 7, p= 14250: then 2c+28+
m = 11000 r; also
3.
4c + 48
X
+1=
2c+28+ m
3ry2
2a²+p=
ry² =
100.3636 = y²; and = 76663.
a²
25750n: from which we have
94
PART SECOND.
J
pry2
a²
= 109250000
p²
n²
|
4
=203062500
=165765625
Sum 478078125; its square root is 21865,
from which take and we have 9990 = x;
n
2'
from which take P
sp
XC
-x+
put2
xa2
(= 1095) and
we have the weight of water 8895lb.
In the first Example, every square foot of
the piston raises 12881b.; and in the second,
1413lb. In the first, the strokes per minute
are 18.75; in the second, 17.96; which, mul-
tiplied by the weight raised at one stroke, gives
25377 and 24150, which difference arises from
the superior weight of the beam, &c. in the
second Example.
Had the value of a been sought, as in Prob.
XXXV. neglecting the weight of the beam, &c.
in the first Example it would be found 1236,
and the strokes per minute would be 24, hence
the weight raised per minute = 29664lb.; in
the second Example, the weight [per stroke,
and the strokes per minute, would be the same
as in the first. Hence, computations on the
power of engines, or machines of any kind,
ON STEAM ENGINES.
95
must be erroneous when the weight or resis-
tance of the machine is neglected.
When an engine is employed to raise a large
quantity of water to a little height, the spear,
or pump-rod, is not heavy enough to lift the
piston with a due velocity; hence it has been
common to load that end of the beam: but it
would certainly be an advantage to make the
end over the pump something longer, so that
by its increased weight it may bring up the
piston with a proper velocity, and also make a
longer stroke in the pump, and of consequence
bring up a greater quantity of water (see Prob.
XIX, XX, and XXI). The theory considers
every part of an engine perfect; but as this
can scarcely ever be true, it may be an advan-
tage to make the load less than the theory
assigns, in order that it may strike faster, by
which means the loss of water by the piston,
through the valves, &c. will in part be dimi-
nished. And if the method of computing the
power in the last Problem should be thought
too intricate, an engine constructed by the
Theorems in Prob. XLI. will, if well executed,
be pretty near the maximum.
A
'
Treatise on Mills.
PART III.
ON THE VELOCITY OF FLOWING WATER.
To determine the quantity of water dis-
charged in a given time through given aper-
tures, and at different depths below the surface,
is, in many cases, of great importance. Sir
Isaac Newton, in his Principia, Book 2, Theo.
8, Prob. 36, has demonstrated that the velocity
of water flowing through holes in the bottom
or side of a vessel, ought to be equal to the
velocity which a heavy body would acquire in
falling through a space equal to the distance.
between the surface of the water and the place
where it is discharged. Hence, at the depth
of 16 feet, a stream of 32 feet in length ought
VELOCITY OF FLOWING WATER.
97
to flow out in one second of time.
And from
the laws of falling bodies, it follows, that as
the square root of 16, is to the velocity of the
stream flowing out at that depth; so is the
square root of any other depth, to the velocity
at that depth: that is, the expence of water
through equal apertures is directly as the square
roots of their depths. But Sir Isaac, in making
experiments, found the velocity thus determin-
ed to be too great, which in different cases he
corrected. The friction against the sides of the
hole, and the oblique direction of the particles
of water before they reach the hole, both tend
to diminish the velocity of the stream. And
if these causes could be removed, especially the
latter, the Newtonian theory would certainly
be confirmed by experiment; or rather, expe-
riment would exactly agree with theory. If
we suppose water running into the top of a tube
of equal diameter, and that there is no attrac-
tion, or friction, between the particles of water
and the said tube, the velocity of the water, or
of each particle at the bottom, will be the same,
or equal to that which they would have ac-
quired in falling through the same space, with-
out the tube, toward the earth. Hence to
obtain the true velocity, under different circum-
stances, we must correct the computed velocity
by experiments. And in order to satisfy my-
0
98
PART THIRD.
;
t
self of the accuracy of those made by others,
I have taken the trouble of making a consider-
able number; a few of which I will insert.
>
From the experiments made by some authors,
it appears, that the velocity of effluent water is
much less than assigned by the Newtonian the-
ory: so much less, that they have concluded the
velocity ought to be the same as that acquired
by a body falling through a space equal to half
the depth. But this must be erroneous ; as the.
observed, or real velocity, can never exceed that
assigned by a just theory, whereas it does exceed
that assigned by this theory, but from impedi-
ments, may be expected to fall short, more or
less. When I began to make experiments, I
wished, as much as possible, to get clear of these
obstructions, &c.; and, from the recommenda-
tion of authors, I began with making the aper-
tures in plates about th of an inch thick: the
result of which is contained in the following
Table, where it appears that the observed velo-
city, at the depth of 8 feet, falls 44 feet short
of the computed.-I afterwards tried various
forms, all of which gave more water than the
thin plate. But as my view was to obtain the
greatest velocity, I shall take no notice of any
but the cone, which I found to be the best.
This I made of brass, about th of a foot in
·
VELOCITY OF FLOWING WATER.
99
length, and the top diameter about twice as
much as the bottom, or aperture. The stream
discharged through this is remarkably different
from that discharged through the plate. This
appears like a piece of crystal glass, to the dis-
tance of some feet, more or less, according to
the head; neither has it that contraction just
below the aperture as observed in one flowing
through a thin plate; and the observed velo-
city at the depth of 7 feet, only falls 14 foot
short of the computed.
PROCESS.
The aperture was first bored near the intend-
cd size; it was then finished with a piece of hard
steel wire, one end of which was made like a
square pyramid, and the other fixed in the spin-
dle of a lathe. The wire was afterwards broken
into a number of pieces, which were placed
close to each other on a diagonal scale, and the
sum of their diameters observed; they were
also measured by a screw micrometer; all the
different pieces were measured by several gentle-
men, who never differed so much as th part
of an inch in the diameter of a piece. And from
the velocity of the water through the different
holes, or those made by different wires, I have
reason to conclude that their diameters were all
measured to the greatest degree of accuracy.
100
PART THIRD.
:
To obtain the quantity discharged in a given
time. An assistant closed the aperture with a
finger till the tube was full, and held the pen-
dulum of a half-second time-piece with the
other hand; then, removing both hands at the
same instant, the water was suffered to flow as
long as convenient, (by a constant supply, the
head of water was always the same during the
experiment) and was stopped at the end of any
given time, to the greatest degree of accuracy.
To find the velocity.—The water discharged
was weighed, reduced into cubic inches, and
divided by the area of the aperture, in inches;
by which the length of the stream run out in
the whole time was known.
Experiments, with the aperture made in a plate
about th of an inch thick.
TABLE. I.

Number.
Head, in feet
Area of the
hole, in
inches.
Weight run
nute, in oz.
out în a mi-
avoirdupoise]
Velocity per
second, by
computation.
Velocity per
second, by
experiment
Difference at
the depth of
16 feet.
1
1.375.0055
16.97
9.38
7.4
2
2.2
34.5
.0055 21.4
.0055 30.6
11.86
9.3
6.7
16.9
13.35
48.
.0055 40.8
22.62 17.8
51.375 .01227 37.94
9.38
7.12
62.2
.01227 | 48.1
11.86
9.41
6.8
7 4.5
.01227 68.4
16.9
13.37
8 8.
93.66
.01227 92.2
22.62
18.1
.0046 23.17 15.31
12.08
6.6
10 8.
.0046
34.39 22.62 18.
11
3.66
.007
35.36 15.31 12.12
6.5
12
8.
.007
90.9
22.62 18.05
133.66
.09
454.
15.51 12.106
6.6
14 8.
.09
674.
22.62 17.97
VELOCITY OF FLOWING WATER. 101
In the six following Experiments, the Water passed
through a cone oth of a foot in length.
TABLE I. CONTINUED.

Number.
Head, in fect.
Area of the
hole, in inches.
Weight run ont
în a minte, in
ounces avoirdu-
poise.
Velocity se-
cond, by com-
putation. --
Velocity of se
cond, by ex-
periment.
Difference at
the depth of 16
feet.
15
3.61 .0046 | 26.87
16 3.61 .007
15.2
41.16
'17 3.61
.0141 85.3
13.9
14.23
14.52
2
18 7.
.0046 37.43
21.16 19.53
19 7.
.007
57.4
19.68 2
20
7.
.0141117.
19.91
The following Experiments were made by the
Abbé Bossuet: his reservoir was 3 feet square
within; the orifices through which the water
issued were made in brass plates, about th
of an inch thick.
N. B. The measures are taken by the Paris foot.
Height of the Water above the centre of the hole,
11 feet 8 inches and 10 lines.
TABLE II.
By a circular orifice, 6 lines in diameter, 2311
1 inch
do.
cubic inches
9281
2 inches
do.
37203
# minute.
102
PART THIRD.
By a square orifice, 1 inch by 3 lines.. 2933
cubic inches
1 inch by 1 inch 11817
# minute.
2 inches square
.47361
Height of the Water, 9 feet.
By a circular orifice, 6 lines in diameter, 2018 7 cubic inches.
1 inch
do. 8135
Height of the Water, 4 feet:
7
minute.
By a circular orifice, 6 lines in diameter, 1353 cubic inches.
do. 5436 minute.
1 inch
In English measure, the head to the six first
experiments is 12.5104 feet; the computed
velocity is 28.296 feet; and the observed, at a
mean, is near 17 feet.
Experiments from F. D. Michelotti's Speri-
menti Idraulici, 1767. The reservoir was
20 feet high, and 3 feet square within, and
had openings at different distances below the
top. It was supplied by a canal 2 feet wide,
the bottom of which was horizontal. The
water ran into a cistern, whose area was 289
square feet, of an uniform figure, and the
quantity was measured by taking its height
in this cistern. The measures are French.
VELOCITY OF FLOWING WATER.
103
+
TABLE III.

Size and kind Head above the Time of
centre of the hole.running.
of hole.
Feet, inch. Lin. Pa.
Minutes.
Cubic feet of
water expended.
Feet. Inch. Lin.
463 7 3
6 7 4 3
10
6 10 2 8
12 566 5 6
Square, of
11 -8 16
3 inches.
11 9 9 10
10
851695
612 1 5
21 8 3 6
5
415.5
3
21 8 7
0
6
499 2 8
Square, of
2 inches.
6 7
6
0
15
329 9 8
11 5
1 4
15.
423 5 7
21 5 3
7
10
385 4 0
Square, of
69 1
O
30
158 6 7
11 10 8
1
1 inch.
24
163 9 6
21 6
1
0
60
562 11 4
Circular of
6 8
4
0
15
542 10 6
3. inches
11
7 1
0
12
570 11 8
diameter.
21 7 4 0
8
521 3 7
Circular of
6 9
5
0
30
488 8 3
2 inches
11 8 8
0
28
589 6 5
diameter.
21 10 10
20
575 5 10
Circular of
6 10 6
0
60
247 4 3
1 inch
diameter.
11 8 11 0
60
324 1 5
22
0 2 0
60
444 6 5
In the first Experiment, the head, reduced
to English measure, is 7.049 feet, and the com-
puted velocity at 21.2 feet. The quantity run
out in ten minutes, in French measure, is
463.604 cubic feet; the area of the hole is
.0625 feet, by which divide the quantity, and
we have 7416.06, the feet run out in ten
minutes, which is equal to 12.36 French, or
13.175 English feet, in one second; or, the
104
PART THIRD.
•
true quantity is to the computed, nearly as 5
to 8: and nearly the same result is drawn from
all the Experiments made by this author, of
which I have copied but a few.
2
Experiments by Messrs. Brindley & Smeaton:
the water extended over a large surface, the
depths measured from that surface to the
top of the holes.
TABLE IV.

Size of the hole. Head, in feet. Time in which 20
cubic feet run out.
1
9 min. 22 sec.
2
6
40..
1 inch square.
3
5
20€
4
4
44
5
4
14
½ inch square.
6
17
33 ..
TARLE V.

Notches 6 inches Time in which 20 cubic
wide.
feet run out.
1 inch deep
1/
27%
3套
​74 2 1
7 min. 16 sec.
55
..
19
61
0
:::
33
30
5
0
46 ..
14
5
26
1/
3
55
5*
0
42
VELOCITY OF FLOWING WATER.
105
Experiments by Professor Helsham, of the
University of Dublin.
TABLE VI.

Head, in Diameter of the
Time, in
Weight, in
feet.
hole, in inches.
seconds.
grains.
4
.1
10
2944
.4
4
.5
.8
+38
47040
72960
•
2
.1
178560
2087
2
2
.5
2
∞o ir f
.4
.8
33600
51840
128400
In the first fourteen Experiments in Table I.
the velocity, or quantity discharged, is some-
thing greater than in the following Tables,
though the orifices were made in flat plates:
this is owing to the form of the lower part of
the tube being the frustum of a cone, and the
plate being half an inch in diameter. In the
six last experiments, where a cone is substituted
for the plate, we have the velocity considerably
increased: so much as, at the depth of 16 feet,
to fall only 2 feet short of the computed velo-
city. But if the laws of hydrostatics assigned
no greater velocity to flowing water, than that
which would be acquired by a heavy body in
falling through half the depth, we should have
an effect produced without a cause. For the
velocity at the depth of 16 feet should be, ac-
P
106
PART THIRD.
cording to that law, the same as a body would
acquire in falling through 8 feet, or 22.627 feet
per second; whereas it is, in fact, 30 feet. And
whatever advantages I may have taken, in re-
spect to the form of the containing vessel, this
alters not the pressure of the fluid, or the
laws of nature, but tends to remove the impe-
diments.
But from these Experiments, we are not to
conclude, that the velocity of water, as flowing
through orifices made in large surfaces, is in the
same ratio. Sir Isaac Newton concluded, that
the observed, or real velocity, was less than the
computed, in the ratio of 1 to the square root
of 2, or as 1 to 1.414; the Abbé Bossuet, as 100
to 150; and F. D. Michelotti, as 5 to 8, &c.-
The quantities in the foregoing Tables, reduced
to the same denomination, stand as below:-
Newton
Bossuet
.707
.615
Banks -
-
- .750
Michelotti
- .625
Helsham
.705
Smeaton
.631
6) 4.033
Mean.672
VELOCITY OF FLOWING WATER. 107
Bossuet and Michelotti have made Experi-
ments upon the largest scale of any I have heard
of, though they do not give the greatest velo-
city; yet they were both agreed with Sir Isaac
in the method of computing it: hence, they
could not be biassed to favour a different theory.
If we take the mean velocity of the above Expe-
riments, we find it to be of the computed;
or their ratio is as 5 to 8: viz. at the depth or
a foot, the actual velocity from them is 5 feet,
and in the same proportion for any other depth.
EXAMPLE.
Given the depth 6 feet, to find the velocity?
Let d = the depth in feet.
"the velocity required.
Then, .672 × 8 √ d = v ; √ d = 2.449,
which × 513.163, the required velocity.
When water is discharged through perpen-
dicular sections, the velocity at the bottom will
be something greater thah at the top of the
orifice; but if the depth or breadth of the ori-
fice be but little, compared with its depth below
the surface of the dam, we may take the depth
of the centre of the hole for the mean depth,
without sensible error.
108
PART THIRD.
}
•
RULE.
Measure the depth in feet, extract the square
root of that depth, and multiply it by 5.4, which
gives the velocity in feet per second: this multiplied
by the area of the orifice in feet, gives the number
of cubic feet which flows out in one second.
EXAMPLE.
Let the depth be 10 feet, the breadth of the
orifice 7 inches, and its horizontal length 4
feet; required the quantity of water expended
in one second?
4
The square root of 10 is 3.162, which mul-
tiplied by 5.4, gives 17.0748 feet, the velocity
per second. The area of the orifice is ¹ x 7 =
2 feet, by which multiply the velocity, and
we have 39.84 cubic feet per second.
12
If the breadth of the orifice is great, com-
pared with the head, we must compute the ve-
locity at the top and bottom, and find the area
of a perpendicular section discharged in a given
time.
EXAMPLE.
Given the perpendicular depth of the orifice
2 feet, its horizontal length 4 feet, and its top
1 foot below the surface of the water in the dam,
to find the quantity discharged in one second?
VELOCITY OF FLowing water. 109
See Fig. XX, where B is the surface of the
water, BA the depth of the upper side of the
orifice, and BD the depth of the bottom thereof.
BD is the axis of a parabola, AC and DG ordi-
nates which represent the velocity of flowing
water at these distances from the vertex; we
have, therefore, to find the area of the section
ACGD, which will be done by finding the area
of BDG, and deducting that of BAC from it.
Put DB =d, sc = a, DG = n, BA = c.
Then the area of BGD = and that of BAC=
2ca
; hence
3
2dn 2ca
3
3
2dn
39
= area of ACGD. For,
by the above rule, the velocity at the top is
5.4, at the bottom 9.24, and the area required
= 14.82, which multiplied by the length,
gives 59.3 cubic feet per second.
Of the Quantity of Water discharged through
Slits or Notches cut in the side of a vessel or
dam, and open at the top.-See Fig. XXI.
If the surface is considered without motion,
and the velocity below increasing with the
square root of the depth, then the area of the
perpendicular section will be a part of a para-
bola, and will be found by multiplying the
velocity at the bottom by the depth, and taking
two-thirds of the product for the area, which
t
110
PART THIRD.
again multiplied by the breadth of the notch,
gives the quantity or number of cubic feet dis-
charged in the given time.
For example,
Let the depth of the notch be 5 inches, and
the breadth 6 inches; required the quantity'
run out in 46 seconds?
The depth in feet is .4166, its square root is
.6455, which multiplied by 5.4 × 3 = 3.6,
gives 2.3238; this multiplied by .4166, the
depth, produces.96825, which being multiplied
by the breadth, half a foot, or .5, gives .48412
feet
per second; this multiplied by the time, 46
seconds, gives 22.269 cubic feet.—The sixth
Experiment in Table V. gives 20 cubic feet.
For another example,
Let the depth be 3 inches, the breadth 6
inches; required the quantity which flows over
in 93 seconds?
Let d the depth in feet.
b the breadth in feet.
n = 3.6.
Then, 3.6 dbvd=cubic feet per second: in
this example, d.2604, b = .5, √d = .51;
these multiplied together, produce 22.227 cubic
VELOCITY OF FLOWING WATER.
111
feet; more than the experiment by 24 feet,
nearly.—At the depth of 1 inch, the computed
quantity is 18.727 cubic feet, but by the expe-
riment it is 20. Also, through a notch 1 inch
square, the quantity, as near as can be mea-
sured by experiment, is 8.6 cubic feet, and by
computation only 7.3. From which compari-
sons it appears, that all the experiments have
not been equally accurate. In the above me-
thod of computing, the surface of the water is
supposed to be without motion; this is not
strictly true in any case, but more especially in
rivers; though the deviation from experiment,
in still water, is not great. And if we wish to
take the velocity of the surface into the compu-
tation, we may proceed as in finding the quan-
tity which flows through an orifice just below
the surface.
Letv the velocity of the surface: then
will
າ
5.4
h, the head which would produce
that velocity; if this is added to the depth of
the notch, we shall have the following Theo-
rem, viz. x d + h x 5.4 vd - ?
2hv
3
= the
area of the section, which, multiplied by the
breadth of the section, gives the number of
cubic feet
per second.
112
PART THIRD.
}
EXAMPLE.
Let d = 1 foot, the depth of the notch; b=
1 foot, the breadth; v = 1 foot per second;
2
h =.=.034.
5.4
Then d+h=1.034, ✔d 1, and
=
3/
=
2hn
3
.0228; or 1.034 X 5.4 X 1 x 3.7003,
the area; ord+h × 3.6√d_2hv
3
the area,
which multiplied by b, the breadth, gives 3.7
cubic feet per second.
In this example, by taking the velocity of
the surface to be one foot per second, the quan-
tity run out in a second is one-tenth of a cubic
foot more than it would have been had the
surface been supposed without motion.
On the impulsive Force of effluent Water.
The pressure of water upon a given surface
is directly as the depth, whatever may be the
figure or magnitude of the containing vessel or
reservoir: but the velocity is as the square root
of the depth, and the impulse as the square of
the velocity, or as the depth. In addition to
the demonstration already given, I shall add
the following observations:
•
VELOCITY OF FLOWING WATER. 113
1. The depth of the water may be consi-
dered as the power which projects or impels
the flowing stream.
2. The quantity and velocity conjointly are
the effect of that power.
3. Could we consider the velocity alone, and
suppose the power to act upon a single parti-
cle, in that case, twice the depth would pro-
duce a double velocity in the said particle.
4. Also, if a given power communicates a
certain velocity to one particle, double that
power would communicate the same velocity
to two particles.
5. Therefore, if a given power gives a cer-
tain velocity to one particle, it will require four
times that power to communicate two degrees
of velocity to two particles. And in water
flowing through a given hole, the quantity will
increase directly with the velocity, viz. a dou-
ble velocity must give a double quantity, and
of consequence the power which produces it is
always as the square thereof. From hence we
infer, that the effect of a stream of water flowing
through a given orifice, ought to be directly as
the depth of that orifice: that is, if a stream of
water flows through a hole at the depth of one
Q
114
PART THIRD.
foot, and produces a given effect, a stream
flowing through the same hole, at the depth of
four feet, ought to produce four times the effect,
though the expence of water be but double.
The absolute force of a stream has commonly
been estimated by the weight of a column or
prism of water, the section of which is equal to
the area of the orifice: this is the true measure
of the pressure against a given surface, but the
water in motion ought to produce a greater
effect.
In order to compare the impulse of a given
stream with the weight of the column which
impels it, I made the experiments in the fol-
lowing Table.
MU
FIG. XXII.
The lever or steel-yard NL, moveable on its
centre c, was so fixed, that a point in the plate
N (the head of a hook h riveted into it) was
exactly under the stream s, and the moveable
weight w shifted till the force of the stream
would raise the end L from the prop P. When
the stream was stopped, or the lever removed,
weight was applied to the hook h, till the end L
was raised from the prop, as by the stream; by
which means the force of the stream, compared
with a dead weight, was obtained. In the third
VELOCITY OF FLOWING WATER. 115
column of the Table, we have the weight of a
cylinder of water, the length of which is equal
to the depth in the first column, and the section
equal the area of the hole in the second; and
while the hole remains the same, the weight
must be exactly as the depth; and also in the
fourth column, the force, though more than
the weight, is still directly as the depth; or,
the forces, as measured by experiments, though
they differ a little, are near enough to prove
that they increase with the square of the velo-
city, or with the depth, directly.
TABLE.

Depth, Area of Weight of the per-
in feet. the hole. {pendicular column.
Force on the
steel-yard.
Dwts. Grs.
Dwts. Grs.
1.5
.0055
Ο
25
છે
0
2.0833
.0055
1
11
2
18
8.
.0055
5
13/
10
10
1.25
.02259
3
14
6
0
1.5416 .02259
4
10
7
6
8.
.02259
22
21
38
6
2.375
.0141
4
7
0
3.458
.0141
6
4
10
6
7.0416 .0141
12
131
21
10
9.3125 .0141
16
14.8
28
5
But the force of a stream, or rather the im-
pulse, cannot be measured by its effect on a
wheel, when that wheel is confined in a channel;
for in that case, the stream, when it has struck
the float-boards, cannot make its escape, and
is therefore heaped or raised against the floats
much higher than it would be if at liberty to
pass.
116
PART THIRD.
On Emptying of Vessels.
The velocity with which water flows through
orifices may be obtained by knowing the time
in which a cylinder, &c. is emptied by the water
running out through a hole in the bottom.
Let x the depth, in feet.
z = the area of the falling surface, in inches.
n = the area of the stream, or orifice, in
inches.
s = 16 feet, the space through which a body
descends, by gravity, in one second.
m = 32 feet, the velocity acquired at the
end of one second.
Then, Ass: m :: √x:
As√s:
m↓ x
the velocity
of the spout per second, at the first instant.
2√89
m √ x nm √ x
And, As zn::
the velocity of
No
nm√ x
the falling surface
: 1″ : : x:
z√8x
nm√ x
second.
Also, As
per
the fluxion of the time of emp-
tying; the fluent of which is
22
SX,
nm
✓s, =
-2√x
n√s
Experiment 1. A cylindrical tube 3.166 feet
long, and 2.705 inches in diameter, was ex-
hausted in 3 minutes and 16 seconds, through
a hole the area of which was .0141.
VELOCITY OF FLOWING WATER. 117
Experiment 2. The area of the cylinder and
orifice the same, the length of the tube 6.458
feet, the time of exhausting, by observation,
is 4 minutes and 40 seconds.
In Experiment 1,
รูป #
10.23144
= 3 mi-
2√3
.0564
nutes and 1 second, which would be the true
time, if at the depth of 16 feet the velocity was
32 feet per second. In Experiment 2,
14.605668
.0564
z√x
= 4 minutes and 19 seconds, the time
of exhausting, by theory.-From these experi-
ments, to find the velocity per second, when m
=2s. If t the time of exhausting, we have,
from the above expression,
2
t; from which

we find s, and from the first experiment
is equal to
tn
10.23144
2.7636
= 13.6974 feet: in the se,
cond experiment, s=
14.605668
3.948
= 13.6863 feet.
In these experiments there is no difficulty in
observing the time to half a second, or nearer.
The length of the tubes can also be truly mea-
sured; but to obtain the area to a greater de-
gree of accuracy, the water was weighed, re-
duced into inches, and the section computed.
Taking the mean of these two experiments,
at the depth of 13.6918 feet, the velocity is
118
PART THIRD.
27.3836 feet per second. And As 13.6918
: 27.3836 : : √16: 29.6 feet, the velocity at
16 feet, according to these experiments.
Experiments on the Velocity with which Water
flows through syphons.
5
FIG. XXIII.
AB is a vessel, &c. containing water, filled to
the line ss; sub a bended tube, or syphon, sv
the shorter, vb the longer leg; ve the perpen-
dicular altitude of the crown of the syphon
above the level of the water to be conveyed
through it; so the perpendicular height of the
difference of the two legs: the whole being
filled, this difference is the power which gives
motion to the whole; for if both ends were
placed in the same vessel of water, whatever
might be their lengths, their endeavour to de-
scend would be as the perpendicular heights,
and these being equal, there could be no
motion. When v is not elevated more than
30 feet, the water in vb begins to descend, and
the weight of the atmosphere causes that in
the vessel AB to follow up the tube sv.

Perpendicular
height of the
syphon above
the level of
water.
Perpendicular
length below
the level.
Area of the
orifice.
Weight per mi-
nutë in ounces
avoirdupoise.
Computed
minute.
quantity per
NPP
21 In.
39
58
62
62
97
952.
24.
27.5
26.5
55.75
35.75
9.25
20.
.0141
Square root
of sb.
3.75
4.075
3.88
4.158
4.095
4.064
4.899
5.244
5.147
5.819
5.904
7.466
4.63
4.76
5.98
2.245
2.41
3.041
3.317
3.542
4.472
VELOCITY OF FLOWING WATER. 119
Without regard to the height of the top of
the syphon above the water, the quantity or
weight discharged is nearly as the square root
of the height sb. For, though the weight of
the water in the tube does for a moment retard
the velocity, yet when once put in motion,
that resistance, by these experiments, is not
worth notice. And while the top keeps free
from air, we may compute the velocity by
taking the difference of the legs, and proceed-
ing in the same manner as in finding the velo-
city through the bottom or side of a vessel.
Experiments on the Velocity with which Water
ascends into a vacuum, by the pressure of the
Atmosphere.
To make these experiments, I procured a
number of tubes, of different lengths, the whole
when screwed together was near 40 feet long;
these were fixed in a stair-case, in such a man-
ner that I could make use of the whole or of
a part, as the experiment required; the highest
was furnished with a stop cock at the top, so
that when the water was raised by a small pump,
by turning the cock, the tube below always
remained full of water. Next, the receiver,
Fig. XXV. was exhausted, accurately weighed,
then screwed upon the pipe or tube, the cock
opened, and the water suffered to flow into the
L
120
PART THIRD.
vacuum for any convenient time, which was
measured by a time-piece. The receiver was
then unscrewed, and weighed again, by which
the weight of the water which entered in a
given time was known; and as the area of the
orifice was also known, the velocity was easily
computed.

Number.
123
8
45RO7∞
3
8
10
∞ ∞ ∞
Height at which
the water is
delivered.
Time, in
seconds.
Weight of
water raised
in ounces
avoirdupoise.
Cubic inches.
Area of the
hole.
Velocity per
second, in feet.
8 inches
43
26
45
27.5
60 36
44.92.002356 36.95
47.52
62.2
|
37.35
36.66
36 22
38
37.33
10
44
27
46.65
37.42
6
4.5 feet
36
20
34.56
33.95
4.5
47 27
45.65
34.3
7.4..
50 27
46.65
33.00
9
7.2..
49 26.4
45.62
32.9
10
7.2
51
27.2
47
32.7
11
7.5.
60
32
55 29
32.59
12 13.8
60
26.3
45.44
26.78
13 13.8
60
26.5
45.79
26.99
14
18.2
60
23.7
41
24.17
15
25
60
16.5
28.51
16.8
16
25
60
17
27.64
16.3
17 32
60
6.76 11.68
6.89
When these experiments were made, the
barometer stood from 29.5 to 30 inches, and
as the pressure is frequently varying, the velo-
city of the rising water must also vary. At
the surface of the water, under the greatest
and least pressure, the velocities would be in
:
VELOCITY OF FLOWING WATER. 121
the ratio of 37.6 to 36. At the altitude of 16
feet, as 30 to 27.
At the height of 26 feet,
as 23 to 17, &c.
In these experiments, the
area of the hole is small, compared with the
area of the lower part of the tube: if the tube
was equally wide, as in the lower part of a
pump, the velocity of the water would be
much less. And when a column of water is
to be moved by the weight or spring of the
air, as in a pump, the water is not instanta-
neously put in motion; and the longer the
tube, the longer is the water in acquiring its
greatest velocity.
N. B. In the above experiments, I frequently
made the vacuum without an air-pump. Upon
the tall tube, above the cock, I screwed as much
more tube as made the whole height about 36
feet; then an open receiver, furnished with a
stop cock at the top, was screwed upon the
tube, the whole was filled with water, and co-
vered with leather and a plate, with the jet-
pipe and cock; after this, the cock in the tube
was opened, and the water descended out of
the receiver and down the pipe or tube, till
the pressure of the air could support it: the
cocks being turned, the receiver was unscrew-
ed, perfectly exhausted.
R
A
Treatise on Mills.
PART IV.
EXPERIMents on CIRCULAR MOTION.
In this part, many of the principal Theo-
rems and Problems contained in the first and
second parts of this work are confirmed by
experiments.
The machine, Fig. XXIV, is useful for
making experiments on circular motion; and
also for comparing the effects produced by a
given weight in falling through a given space,
when applied at different distances from the
axis, &c. The cylinder a is 2 inches and B 4
inches diameter. The wheel w has 84 teeth,
and the pinion P has 8. The balls c c may be
of any weight, and fixed at any distance from
the centre G. In a rod or arm revolving round
a centre, it will be as the velocity of any point
!
EXPERIMENTS ON CIRCULAR MOTION. 123
in that arm is to its distance from the centre, so
is the velocity of any other point to its dis-
tance, &c. The balls c a make 10 turns while
A
the cylinder ▲ makes 1; therefore, if the dis-
tance at which they are placed be multiplied by
10, the product will be the distance at which
a body must be placed from the axis of the
cylinder A; and to revolve with it, the velocity
of which shall be the same as that of the ball c.
For example,
Let the balls be at the distance of 6 inches
from G, this multiplied by 10, gives 63, at
which distance a body revolving round with
the cylinder A,' would have the same velocity
with the balls c c. But their central forces,
being as the squares of the velocities divided
by their distances, would be different: in this
case, as, for their velocities are equal, or
vv, but their forces are and
Ð
d'
In the machine, the wire arms are each 8
inches long, and weigh 22 dwts. together; the
distance of the centre of gyration is 4.61 inches
from their centre, where the resistance is equal
to their weight, but reduced to the end of the
arm is only equal to 7.33 dwts.; and at any dis-
tance d the resistance will be =
4.61² × 22
d²
124
PART FOURTH.
EXAMPLE.
Let r the radius of the cylinder from
which the weight м is suspended.
s the distance & c X 10.5.
Then will
72
be the force exerted at c to
give motion to the balls.
Let r = 1.
s = 84.
M = 8 97.
G+ c = 8 ez.
Then will
.0011336
Mp2
=.0011336 oz. the moving
power; the resistance is the moving power
itself, (.9011336) the arms reduced to the
end, (.3666) and the balls, (= 8), the sum
is 8.3677996 oz., the whole resistance. If
the moving power is divided by this, we have
.0001356, the accelerating force
8.3677996
compared with gravity, which multiplied by
16, gives .0021469 feet the first second. And
As 1": .0021469 :: 1002: 21.469 feet, the
space through which the body would descend
in 100 seconds. By which process the follow-
ing experiments may be compared with each
other, and with the theory.
:
•
EXPERIMENTS ON CIRCULAR MOTION, 125
For, let w the weight of the fly.
:
tthe time of descent, in seconds.
feet passed over by м in the time t.
d= 16 feet.
the space passed over by the fly,
in the time t.
Then will n =
Mr²
F
MST
ws² + Mr²
x dt, Theo. 1.
-.
208² + My X dt?, Theo. 2.
Mdrata
Mr2
w=
Fs2
82
Mrdt2
Mr2
Theo. 3.
or w=
ns
829
FW82
M =
dr²t² — Fr²)
Theo 4.
t =
Part II.
Fws² F
Mdr²
+ Theo. 5.-See Prob. XV.
In these Theorems, the resistance of the air
is not considered; but the following experi-
ments will be sufficient to convince us that when
the moving body is small, and the velocity
great, it will make a difference in the conclusion,
as it prolongs the time, &c. And although it
is of little importance to consider its effects on
heavy bodies which move slowly, yet in making
experiments to prove the truth of a theory, it
126
PART FOURTH.
becomes necessary to take notice of every im-
pediment. The weights screwed upon the
arms were 2.5 inches long, 1 broad, and a little
thicker at the middle than at the ends (see Fig.
XXVI.); these could be fixed so that either
the end or the flat side should strike directly
against the air.
Experiment 1. The fly being fixed to meet
with the least resistance, a weight of 5.7 oz. sus-
pended from the cylinder A, descends through
9 feet in 62 seconds.
Experiment 2. The fly being placed in a ver-
tical position, so that the flat side might press
against the air, 15 oz. suspended from the cy-
linder A, descends through 9 feet in 62 seconds;
but when the falling weight has acquired a ve-
locity of 2 inches per second, it ceases to be
accelerated, or moves with an uniform motion.
Experiment 3. The fly being placed or fixed
to meet with the least resistance, 7.3 oz. at the
cylinder a descends through 5 feet in 40 se-
conds, at the cylinder в through 5 feet in 20
seconds.
A
B
Experiment 4. The flat side being set to
move against the air, 7.3 oz. suspended from
EXPERIMENTS ON CIRCULAR MOTION. 127
B falls through 5 feet in 23.5 seconds, but sus-
pended from A, in 55 seconds.
}
Observations.—1. When the velocity is the
same, the resistance, so far as it arises from the
friction and inertia of the machine, must be the
same. 2. In experiments 1st and 2d, the ve-
locities are the same, but the weights or powers
which produce them are 5.7 and 15; hence
their difference 9.3 is employed to overcome
the resistance of the air. 3. In both experi-
ments, when the motion is uniform, the velo-
city of the fly is 14 feet per second; and 9.3
oz. divided by 84, gives .11071 oz., the force
exerted on the fly to overcome the resistance
of the air. 4. The difference of surface op-
posed to the air in the two experiments is 4.7
inches, by which divide .11071 oz., and we
have .0235 oz., the resistance against one inch;
by computation it is .02123 oz. 5. The resis
tance arising from the air being as the
as the square
of the velocity, the 3d and 4th experiments
will be found to agree with each other, and
with theory, but will not if the resistance of
the air is neglected.
In the following experiments, the fly is so
fixed as to meet with the least possible resistance.
128
PART FOURTH.
1
TABLE. L

Power. Cylinder, Fall, inches. Time, see. Turus of
No.
M.
T.
F.
t.
the fly.
5
7.3
A
6.
7.3
B
21.90
7
7.3
B
8
7.3
Α
9. 14.6
A
1L
10 | 14.6
29.2
A
8822248
90
52
152
26
76
13
19
26
28
361
152
26
76
90
26
►
152
--
The resistance of the machine is found by
Theo..3. If the fly is used, its weight must be
subtracted frow w, and a weight is left which is
equal to the whole resistance reduced to the
place of w. But in these experiments the weight
and magnitude of the fly remain the same.
1. It appears (No. 5 and 6), that by increas-
ing the distance at which the power is applied,
we diminish the time of descent, but the power
in falling through a given space produces ef-
fects which are as the times of descent.
2. When different powers are applied to the
same cylinder, as in the 5th, 9th, and 11th ex-
periments, they produce effects which are di-
rectly as the square roots of these powers, and
inversely as the times. For, As 7.3 14.6
:: 36: 52, nearly; and As √7.3 : √29.2 : :
26:52. The effects are the same, and the
times are inversely as the square roots of the
EXPERIMENTS ON CIRCULAR MOTION. 129
:
powers, or the powers are inversely as the
squares of the times, or directly as the squares
of the velocities.
3. From the 5th and 10th it appears, that if
a given weight in falling through a given space
produces a certain effect, double that weight
in falling through half the space produces half
the effect.
4. In the 11th experiment the velocity is
twice as great as in the 5th, but four times the
power is employed to produce it: that is, the
power is as the square of the velocity.
5. When equal effects are produced in the
same time, the powers will be inversely as the
distances at which they are applied, but the
spaces descended through will be directly as the
said distances. See experiments 6th and 10th.
TABLE II.

No.
Power, in
12 4 B 48
13 4B 16 4
14 4 B 8 5.65
1516 A 4 8
16 4 A
44
17 1 B 4 4
18 2, A 4 4
6 26.0952 61 254
1016
2
1
6 26.1904 61 127 2032
2 4
2.8
2032
4
8
1016
2
4
508 1
254
1
6 26.1346 61 179.8 1438.7 1.414
6 26.1904 122 508
6 26.0952122 254
6 26.0476 61127
3 26.0476 61 127
S
Centrifugal
force of the fly.
"
1
:
130
PART FOURTH.
In making these experiments, when the cy-
linder B was used, there was an addition of 11
dwts., and when A was used of 44 dwts., to
the power; which weights alone would turn
the machine, and descend through 6 feet in 26
seconds: so that the power in the Table was
wholly exerted in turning the fly.
The numbers under Force acting on the fly,
are obtained by multiplying the radius of the
cylinder used, by the power, and dividing by the
radius of the fly multiplied 10.5. For exam-
ple, No. 12, the radius of в is 2 inches, which
multiplied by the power, 4 oz., gives 8, which
divided by 84 (10.5 x 8), the radius of the
fly, the quotient is .0952, and so for the rest.
The products of the weight of the fly into
the space it has described, are always as the
force acting on the fly: that is, when the power
employed is, by the above process, reduced to
the fly, the effects are as these powers, whether
the fly be heavy or light, or whether the circle
it describes be large or small.
The space passed over by the fly is obtained
by multiplying the circumference of the circle
in which it moves, by the number of turns.
The relative velocity is the space reduced to
less numbers by division.
EXPERIMENTS ON CIRCULAR MOTION. 131
The centrifugal forces are computed by the
Theorems in the first part; but here the num-
bers are not any real measure, but comparative;
for as the velocity is constantly increasing, so-
is the central force. At the end of the time,
the true centrifugal force, in experiment 12th,
is nearly 17 times the weight of the revolving
body, or 68 oz.; and the true force, in ounces,
at the end of the other experiments, will be
had by multiplying that in the Table by 34.
When the cylinder B is used, the angular
velocity is always the same; as it is also when
A is used (except No. 18), but is twice as great
as when в is used, or the revolutions are per-
formed in half the time.
When the power, and distance at which it is
applied, increase with the radius of the fly, the
angular velocity will remain the same, No. 12,
and 18; for 3 feet of cord uncoiled from a will
produce as many revolutions as 6 feet from B.
A
The velocities are as the square roots of the
powers which produce them, or the powers are
as the squares of the velocities, No. 12 and 17.
When any number of revolving bodies, each
multiplied by the square of its distance from
the centre, have their products equal, by a
į
132
PART FOURTH.
f
given power, equal angular velocities will be
produced, No. 12, 13, 14, 17.
If a given power communicates a certain ve-
locity to one quantity of matter twice, thrice,
&c. that power will communicate the same
velocity to twice, thrice, &c. that quantity of
matter, No. 13 and 17.
If the weight of a revolving body, and time
of a revolution, remain the same, the power will
be as the square of the distance, No. 12 and 17.
The centrifugal forces are as the impelling
powers, when these powers are applied in the
same manner, No. 13 and 17; for the radius of
the circle being the same, the forces are as the
squares of the velocities, or as the powers
which produce them. See Prob. XIII, XIV,
&c. Part II.
Experiments on Water Wheels.
FIG. XXVII. ·
1
A B C D is a water wheel with buckets, the cir-
cumference is 5.6 feet, or the diameter of the
circle passing through the centre of the buckets
is 20 inches. By turning a screw, this wheel
may be taken off the axle, and one of a differ-
ent size put in its place. The cog wheels may
EXPERIMENTS ON WATER WHEELS. 133
also be changed at pleasure; as also the wheels
or trundles on the second axle, which are turned
by the cog wheels. On the second axle is ano-
ther cog wheel, with 84 teeth; this turns an
upright spindle, with 8 teeth or leaves; on the
top of this spindle is fixed a fly, the weight
and radius of which may be varied at pleasure.
}
FIG. XXVIII.
The plate F F is divided into 60 parts, and
the index I makes one revolution while the
water wheel makes 60. The index L is fixed
on the axle of the water wheel, and therefore
makes the same number of revolutions: the
plate GG, over which it moves, is divided into
10 parts. There is also another index, not vi-
sible in the figure, which makes one revolution
while the water wheel makes 600.-By these,
and a time-piece, to measure the minutes and
seconds, &c. the number of revolutions made
by the water wheel in any given time may
easily be known..
The water is conveyed from the cock N into
the trough H, or into the vessel FGE, which has
three apertures or sluices at 1, 2, 3; these aper-
tures are so adjusted by trial, that when the
vessel is filled to F G, if any one is opened, it
will discharge the water exactly as fast as it is
134
PART FOURTH.
supplied by the cock; so that the water acts
upon the wheel both by weight and impulse.
The cistern which supplies the cock is always
kept equally full; that is, the water is returned
by a pump, and the person who works it takes
care to keep the surface always at the same mark.
ON THE APPLICATION OF WATER.
On this subject there have been various opi-
nions; but opinions unsupported by theory or
experiment claim little regard. At whatever
altitude the water might be applied to the wheel,
it has been the practice with many to diminish
that altitude, in order to obtain a head, as it has
been supposed that the impulse produced by
that head would have a greater effect than the
water by its gravity could produce, if thrown
into the buckets immediately from the surface.
And no doubt but it is owing to opinions of
this kind, that the water, which might be ap-
plied at the top, is often caused to strike, or
fall upon the wheel, about 45 degrees from the
vertex. The following experiments, which
have been often repeated, both in public and
private, and with the greatest accuracy and at-
tention, give no encouragement to diminish the
altitude for the sake of obtaining more advan-
tage by the impulse.
EXPERIMENTS ON WATER WHEELS. 135
Whether the effect is measured by the velo-
city, its square, or its cube, every thing remain-
ing the same, it will be granted, that when the
wheel moves quickest, the water is applied to
the greatest advantage.
Experiment 1. The orifice No. 1, is opened,
the water strikes the wheel near the bottom, and
acts by impulse and gravity; the head is equal
to the diameter of the wheel. The velocity of
the stream is 6.5 feet per second; the water
wheel makes 60 revolutions in 7 minutes and 21
seconds, or is turned 8.2 times in one minute.
Experiment 2. The sluice No. 2, is opened, No? Are
the water strikes the wheel near the centre, and
causes it to revolve 60 times in 3 minutes and
57 seconds, or 15.19 times in a minute.
Experiment 3. The orifice No. 2, is shut and
No. 3 opened, the water falls upon the wheel,
with impulse, at 45 degrees from the vertex.
The wheel revolves 60 times in 3 minutes and
28.5 seconds, or 17.26 in a minute.
Experiment 4. The water is conveyed into
the trough H, from which it falls upon the ver-
tex of the wheel; 60 revolutions are made in 3
minutes and 15 seconds, or 18.46 in a minute.
136
PART FOURTH.
Experiments.
Sluice.
In these experiments, the fly makes 21 re-
volutions for 1 of the water wheel, its weight
was 4 oz. and diameter 13 inches. The com-
parative velocities of the water wheel or fly,
will be as the number of turns made in a given
time, or as 8.2, 15.19, 17.26, and 18.46.
In the following Table we have the whole in
one view.
Turns of the
water wheel per]
minute.
Relative
velocity.
TABLE III.

Turns of the fly
per minute.
True velocity
of the fly, in
feet, per second
True velocity of
the water wheel,]
in feet, per se-
cond.
6
7
9 No. 1
3 8.88 2.22 373.3 25.92
8 overshot 9.52 2.38 400 27.77
3.05|1 128.1 8.89
1 No. 1
123
8.2
1
172.2 11.96 .765
22.15 1.417
2 15.19 1.85 319
3 17.26 2.1 | 362.5 25.17 1.61
4 overshot 18.46 2.25 387.6 26.91 1.723
5 No. 1 4. 1 168 11.66 .373
27.69 1.92 323
In these four expe-
22.43.717riments, the fly re-
.829 the water wheel once;
>volves 42 times for
its radius 8 inches.
.888
.284
10
2
6.38 2.09 268
In these, the radius
18.61.595 of the fly is 8 inches,
11
13 No. 1
14
2
15
3
16 overshot
3 7.28 2.38 305.7 21.23
12 overshot 7.72 2.53 324.2 22.51
2.141 134.8 9.36
5. 2.33 315 21.87 .466
5.84 2.72 368 25.55 .545
6.4 3 403 4 28.01 .597)
.679
volutions 42 to 1.
weight 12 ounces; re-
.720}
.199
The radius as
above; weight 4 oz.;
revolutions 63 to 1.
In the above four sets of experiments, which
are considerably varied, a given quantity of
water produces the greatest number of revolu-
tions when applied at the top of the wheel.
EXPERIMENTS ON WATER WHEELS. 137
The ratio of the revolutions when the water is
applied at the top, is to the revolutions when
applied at the quarter, nearly as 32 to 30, or as
16 to 15. For, in the first set, As 2.25 2.1 ::
:
16:14.9. In the second set, As 2.38: 2.22
16: 14.9.
In the third set, As 2.53: 2.38::
16:14.05. In the fourth set, As 3: 2.72:
16.: 14.5.
From these experiments it appears, that for
every 15 revolutions when the water is applied
at the quarter, there will be 16 when the water
is applied at the top of the wheel.
Experiments on a wheel 10 inches diameter.
The water applied at the top produces 60 turns
in 4 minutes and 25 seconds, but when applied
to the quarter, 60 turns in 4 minutes and 52
seconds; the turns per minute in the first case
are 13.58, in the second 12.32; and As 13.58
: 12.32 :: 16:14.51, the number of revolu-
tions, when the water is applied at the quarter,
for 16 when it is applied at the top, or a given
quantity of water in the overshot produces 16
turns of the water wheel in the same time as
it produces 14 when applied at the quarter.
Three quarts of water in a minute, laid on
at the top of the wheel, turns it 60 times in 6
T
138
PART FOURTH.
minutes and 45 seconds; four quarts set on at
the quarter produces the same number of revo-
lutions in the same time. And if the weight
of the fly or the ratio of its revolutions to those
of the water wheel be varied, yet the ratio of
the quantities of water to produce the same
effects in the same time remains the same.
Experiments on the Velocity of Wheels.
In these experiments, the effect is measured
or estimated by the number of the revolutions
which a fly makes in a given time: and although
this is not the true measure of the power of
the water, (part of it is exerted in turning the
wheels), yet it is as much so as the revolutions.
of a mill stone are the measure of the effect
produced by the water; and that velocity which
a wheel has when a mill stone makes the great-
est number of revolutions in a given time, will
certainly be considered as the best. It may be
observed, that these experiments are confined
to wheels on which the water acts by gravity
only, and that the buckets are supposed to be
large enough to retain the water till it comes
near the bottom of the wheel: for if the buck-
ets lose part of the water as they descend, the
wheel, in its present construction, is not doing
EXPERIMENTS ON WATER WHEELS. 139
the most work.—In the following experiments
the quantity of water was always the same; the
water wheel made 60 revolutions, and some-
times more; the time was observed, from which
the number made in one minute was computed.
In order to vary the velocity of the water
wheel, it becomes necessary that the ratio of its
revolutions, to those of the fly, should also vary,
which is effected by changing some of the wheels.
Experiment 1. The water is applied at the
top in this, and all the following experiments
under this head. The wheel makes 15.36 re-
volutions in a minute, the fly 21 for 1; and
15.36 × 21 322.56, the number of revo-
lutions which the fly makes in a minute.
:
Experiment 2. The water wheel turns 12.08
times in a minute, and the fly 28 for 1; hence
the fly revolves 338.24 times per minute.
Experiment 3. The fly turns 44.6 times for
the water wheel once, which is turned 7.67
times in a minute; of consequence, the fly re-
volves 342.08 times per minute.
Experiment 4. The fly makes 59.5 turns for
the water wheel once, and the water wheel
turns 6.02 times in a minute; the fly, there-
fore, turns 358.19 times per minute.
140
PART FOURTH.
Experiments.
But perhaps these four experiments, with
others made with a different fly, may appear
to more advantage as classed in the
Table.
following
Turns of the water
wheel per minute.
Velocity of the
water wheel, per
second, in feet.
Turns of the fly for
one of the water
wheel.
TABLE IV.

Turns of the fly
per minute.
Ratio of the quan-
tity of water in the
buckets.
Quantity per minute
to turn the fly
equally fast.
Turns of the water
per minute,
wheel
when the fly turns
equally fast.
Quantity on the
wheel at once, when
the fly has the same
velocity.
Velocity of the
water wheel in feet,
when the motion of
the fly is equable.
1.
2.
3.
4.
5.
6.
7.
8.
9.
115.361.433 21
322.5
2 12.08
1.127 28 338.2
3 7.67
.716 44.6342
4 6.02
.562 59.5 358.2
5 36
3.36 8.75 315 1
4 36
1
10.
3.36
:
6 28.125 2.62 | 131 | 369.1 1.282 3.11 24
718.18 1.69 21
8 15.58 1.45 25
9 12.57 1.11 31
10 9.52 .8842
11 7.67 .71 52
12 6.4 .59 63
381.8 1.988 2.45| 15
389.5 2.317 2.29
395.6 2.863 2.14 10
400 3.812 2
1.166 2.24
1.47 1.4
1.606 1.666
1.926 .933
7.4 2.4
.7
402.9 4.732 1.90 6 2.8 .56
403.45.7 1.82 5 3.368 .466
The second column shews the turns of the
water wheel per minute, as found by experiment.
'The third is found from the second: for ex-
ample, in the first experiment, 15.36 multiplied
by 5.6 feet, the circumference of the wheel,
gives 86.016, the feet passed over in a minute,
which divided by 60, gives the feet
= 1.433.
per second,
The fourth column is known from the wheels
made use of.
EXPERIMENTS ON WATER WHEELS. 141
The fifth is the product of the second mul-
tiplied by the fourth.
The sixth shews the ratio of the quantity of
water hanging upon the wheel at once, which
is always inversely as the velocity of the wheel:
for instance, the wheel moving with a certain
degree of velocity, every bucket receives a
given quantity, but if the wheel moves twice
as fast, a bucket can receive but half the quan-
tity; or if the wheel has half the first supposed
velocity, a bucket will receive a double quan-
tity. Otherwise, suppose the wheel moves 6
feet in a second, and that a bucket receives 10
gallons; then, if it moves but 3 feet per se-
cond, a bucket will receive 20 gallons, or if 2
feet per second, 30 gallons, &c. In the fifth
experiment, the wheel turns 36 times in a mi-
nute; in the ninth, but 12.57 times: hence,
inversely, As 36: 1 portion of water: 12.57
: 2.863 times the quantity.
By increasing the velocity of the fly, com-
pared with that of the water wheel, we have,
in the last experiment, near six times as much
water upon the wheel at once, from a given
stream, as there is in the fifth experiment, in
which the fly is turned 315 times in a minute;
but in the last, 403 times.
#
142
PART FOURTH.
In the seventh column we have the quantity
of water as found by experiments to produce
315 revolutions of the fly in one minute; and
it appears, that by increasing the velocity of
the fly compared with that of the water wheel,
that a less quantity of water is sufficient to
produce the same effect, or the same number of
revolutions of the fly: for in the last experi-
ment the quantity of water is not half of that
used in the fifth, though the effects are the
same.
The eighth column contains the number of
revolutions which the water wheel makes in a
minute, under the different changes of wheels
in the communication of motion to the fly,
when the fly itself makes the same number of
revolutions per minute.
The ninth column exhibits the comparative
quantity of water hanging on the wheel at once,
when the fly moves equally fast.
The tenth is the velocity of the water wheel,
in feet, when the fly has the same velocity in
all the experiments.
The five following experiments were made
with a wheel of 11 inches diameter.
EXPERIMENTS ON WATER WHEELS. 143
TABLE. V.

← Turns of the fly
for one of the
water wheel.
Revolutions of
the dy per
minute.
13
14
14
9.6
.677 21
.464 | 31
296
31 | 302.4
15
7.31
.353 42
307
16
5.9
.285
52
52
309.75
17 4.94
.238 63
311.55
The speed of the water wheel being dimi-
nished, the revolutions made by the fly in a
given time are increased in number, both with
the large and small wheel. It is true they are
not increased in the same ratio when the velo-
city is much diminished, as in the eleventh and
twelfth in Table first, and again in the sixteenth
and seventeenth in Table second, but this is
owing to the buckets being overloaded, so that
they lost a part of their water too soon, and of
consequence the effect in the two last experi-
ments is not much increased. But if the buck-
ets retain their water till they come near the
bottom, it appears, that the slower the water
wheel moves, the greater its effect will be, pro-
vided the motion continues to be equable. See
Prob. XXXVIII, Part II.
This may also be proved by raising weight by
a cord coiled round the axle of the water wheel.
144
PART FOURTH.
{
The following Table contains seven experi-
ments, in which the velocity of the water wheel
is gradually diminished from the first to the
last; but the effect in the last is the greatest.
TABLE VI.

Experiments. Weight.
Time of rising Velocity, or feet
through 6 feet.
per second.
Effect
produced.
123
lb.
57.5"
.1043
5.21
1
62.4
.0961
9.61
11
69.5
.0863
12.94
4
5
6
7
2 3 4 5
75.5
.0795
15.90
93
.0645
19.35
117
.0512
20.48
142
.0422
21.10
To find the velocity per second. As 57.5":
6 feet 1".1043 feet; and As 62.4": 6 feet
:: 1″:.0961 feet, and so for the others. The
effect is obtained by multiplying the velocity
thus found by the weight raised, as in the first
experiment, lb. multiplied by .1043, gives
.0521, the effect; and in the second, 1 lb. mul-
tiplied by .0961.0961, and in the same man-
ner the effect in all the other experiments is
obtained. In the Table, the effect thus found is
multiplied by 100, or the decimal point is re-
moved two figures, but the ratio is the same.
If it was required to find the weight raised
in a given time, suppose 1 hour, it would be,
As the time of rising through 6 feet is to the
EXPERIMENTS ON WATER WHEELS. 145
weight raised so is 1 hour to the number of
times which the said weight would be raised
through the given space.
For example, As 57.5" lb. :: 3600" (1
hour): 31.304 pounds per hour. In the third
experiment, As 69.5" : 1.5 lb. :: 3600": 77.7,
pounds per hour. In the sixth experiment,
As 117": 4 lb. :: 3600": 123.08, pounds per
hour. In the seventh experiment, As 142″:
5 lb. :: 3600": 126.7, pounds per hour.
Which experiments so far, in conjunction
with those made with the fly, prove that by
diminishing the velocity of the water wheel,
we increase the power.
On the Velocity communicated to a Wheel, by
different Quantities of Water.
See page 17,-where it appears that if a given
stream produces a certain velocity in the wheel,
a stream eight times as large will be required
to communicate double that velocity, or to turn
the wheel twice round in the same time. And
for any other quantity of water which may be
applied, it will be, As the cube root of the
present quantity is to one degree of velocity, so
is the cube root of the other quantity to the
velocity it will produce.
V
146
PART FOURTH.
The truth of the proposition will appear by
the following experiments.
FIG. XXX.
Pieces of brass were screwed upon the end
of the cock, and perforated, by trial, till the
aperture was large enough to deliver the exact
quantity required: for instance, a pint, a quart,
two quarts, &c. per minute, and which quan-
tity was always applied in the same manner.
Experiment 1. One pint of water per minute.
turns the water wheel 60 times in 13 minutes
and 33 seconds.
Experiment 2. Two pints per minute turn
it 60 times in 10 minutes and 42 seconds.
4
Experiment 3. Four pints per minute pro-
duces 60 turns in 8 minutes and 27 seconds.
Experiment 4. Six pints per minute pro-
duces 60 turns in 7 minutes and 18 seconds.
Experiment 5. Eight pints per minute pro-
duces 60 turns in 6 minutes and 18 seconds.
In the following Table we have, in the first
column, the quantity of water applied; in the
second, the cube root of that quantity; in the
third, the comparative velocities as found by
EXPERIMENTS ON WATER WHEELS. 147
the experiments; in the fourth, the number of
turns the water wheel made in a minute.
TABLE VII.

12
and Q
1
1
1
4.42
2
1.2599
1.267
5.6
3 4
1.5874
1.606
7.1
4
6
1.8171
1.859
8.219
5
8
2
2.15
9.52
The number of turns per minute is obtained
by direct proportion: for, in experiment 1,
As 13′ 33″ 60 revolutions :: 60": 4.42 revo-
lutions, and so for the rest.
The velocity is directly as the number of
turns made in a given time; and if in the first
experiment it is represented by 1, in the second
it will be 1.267; for As 4.42 1: 5.6: 1.267,
: :
and As 4.42: 1 :: 7.1 1.606, &c.
:
In the fifth experiment, the quantity per
minute is eight times as much as in the first;
but it may be observed, that the load or weight
upon the wheel is only four times as much as
in the first; for as the wheel moves twice as
fast, a bucket can only receive half as much
water as it would do with the velocity it had in
the first experiment.
148
PART FOURTH.
ON THE SIZE OF WHEELS.
THE fall being given, or the greatest altitude
at which a given stream can be applied to a
wheel, it becomes necessary, both on account
of expence and utility, to enquire what the
diameter of the wheel ought to be. This may
be determined either by theory or experiment.
1. Let us suppose two wheels equally heavy,
the diameter of one 10, and the other 20 feet,
and that the weight is chiefly in the circumfe-
rence, or as much so in one as in the other.
2. Let the same power be applied to the cir-
cumference of each wheel, and each circum-
ference will have the same velocity; hence, the
time of a revolution will be as the diameters
directly, or in the present case as 1 to 2, or the
10 feet wheel will be turned twice for the 20
feet once, as already demonstrated in Prob.
XIV, Part II, and proved by experiment in
No. 12 and 16 in Table II, page 129. In both
experiments the power is 4 oz., and the weight
of the fly or wheel is the same; but in No. 12
the radius is 8 inches, and the power is applied
at the distance of 2 inches; in No. 16 its ra-
dius is 4 inches, and the power is applied at 1
inch: hence the ratio of the effects produced.
EXPERIMENTS ON WATER WHEELS. 149
is exactly the same as if it had been applied to
the circumference of the two wheels; and as
their weights are equal, and they move equally
fast, the effects are also equal: but their revo-
lutions are not performed in the same time;
for, in 26 seconds, one revolves 61 times, and
the other 122, or the revolutions are performed
in times which are as 1 to 2, as above.
3. The power being employed to turn a
single wheel, the velocity of its circumference
will vary with the weight of the wheel, and of
consequence the time in which it revolves: for
if one of the above wheels is made twice as
heavy, it will be twice as long in making one
revolution as it was before.
4. If the power is a stream of water, this
will vary with the velocity of the wheel. Sup-
pose a given stream to turn the wheel with two
degrees of velocity, then if the velocity of the
wheel is but one, there will be twice as much
water upon it, or in the buckets, as when it had
two degrees of velocity: hence, if a wheel of
a given weight has a velocity of 4 feet per se-
cond, one 4 times as heavy would be caused to
move 2 feet per second by the same stream (see
page 113, and 125), not considering the water
as part of the mass to be moved.
150
PART FOURTH.
A
5. Let us suppose a stream of water applied
at the top of a wheel 10 feet in diameter, and
that it turns the wheel in 6 seconds; let the
same stream be applied at the centre of another
wheel 20 feet in diameter; then it is evident,
that if every bucket receives as much water as
before, that the large wheel will be twice as long
in making one revolution as the small wheel,
and therefore by the same cog wheel, &c. cannot
do the same work; and if we encrease the cog
wheel in the same ratio as the water wheel, we
obtain no power by making the wheel larger.
The truth of the above is confirmed by the
following experiments.
Experiment 1. A given stream is applied
exactly at the centre of a wheel 20 inches in
diameter; it makes 60 revolutions in 4 minutes
and 21 seconds.
Experiment 2. The large wheel is removed,
(the cog wheel, fly, &c. remain the same) and
one of 10 inches in diameter is fixed in its
place; the same quantity of water is applied at
the top; and it makes 60 revolutions in 4 mi-
nutes and 15 seconds.
Experiment 3. The water is applied at the
centre of the great wheel, and in addition to
}
i
1
EXPERIMENTS ON WATER WHEELS. 151
the fly, one pound is suspended from the axle,
which is raised through 5 feet in 59 seconds.
The large wheel being removed, and the small
one fixed in its place, every thing else remain-
ing the same, the same weight is raised through
the same space in 55 seconds.
In the last experiment, if the great wheel
produces the same effect as the small wheel in
the same time, the circumference must move
twice as fast, by which the power would be
diminished. See page 138, &c.
Experiment 4. A cylinder is fixed upon the
axle, which has the same ratio to the diameter
of the large wheel as the axle itself has to that
of the small one, or the axle is 3 inches diame-
ter, and the cylinder 6 inches; the water is
applied at the centre of the great wheel, and
the weight is raised in 56 seconds.
In the above experiments, except the third,
there ought to be no difference in the effects
produced by the two wheels but what arises
from the difference of the weight of the said
wheels and their velocities; hence the greater
effects produced by the small wheel is owing to
its requiring a less force to turn it, indepen-
dent of the rest of the machinery, than what
}
152
PART FOURTH.
is necessary to turn the large wheel, or to cause
it to revolve in the same time (see Prob. XIV,
Part II.). For if the wheels were of the same
weight, and the same power applied to the
circumference of each, the small wheel would
make two revolutions for the large wheel one.
ON THE FALL OF WATER.
By the fall, is understood the perpendicular
altitude, measured from the bottom of the
wheel to the surface of the dam, which, when
the water issues upon the wheel at some dis-
tance below the surface, is frequently distin-
guished by head and fall.
The effect produced by a given stream in
falling through a given space, if compared with
a weight, will be directly as that space; but if
we measure it by the velocity communicated
to the wheel, it will be as the square root of
the space descended through, agreeable to the
laws of falling bodies.
Experiment 1. A given stream is applied to
a wheel, at the centre; the revolutions per
minute are 38.5.
Experiment 2. The same stream applied at
EXPERIMENTS ON WATER WHEELS. 153
!
מי.
the top, turns the same wheel 57 times in a
minute.
If in the first experiment the fall is called 1,
in the second it will be 2. Then, As VI:
√2:: 38.5: 54.4, which are in the same ratio
as the square roots of the spaces fallen through,
and near the observed velocity.
In the following experiments a fly is con-
nected with the water wheel.
Experiment 3. The water is applied at the
centre, the wheel revolves 13.03 times in one
minute.
Experiment 4. The water is applied at the
vertex of the wheel, and it revolves 18.2 times
per minute.
And As 13.03: 18.2 :::√, nearly.
From the above we infer, that the circumfe-
rences of wheels of different sizes may move
with velocities which are as the square roots of
their diameters without disadvantage, compared
one with another, the water in all being applied
at the top of the wheel. For the velocity of
falling water at the bottom or end of the fall is
as the time, or as the square root of the space
fallen through: for example, let the fall be 4
X
154
PART FOURTH.
!
!
3
feet; then, As 16: 1 :: √4: ", the time
4,
of falling through 4 feet. Again, let the fall
be 9 feet; then, As √16 : 1″: : √9 : 3″, and
so for any other space, as in the following
Table, where it appears that water will fall
through 1 foot in a quarter of a second, through
4 feet in half a second, through 9 feet in three
quarters of a second, and through 16 feet in
one second. And if a wheel 4 feet in diameter
moved as fast as the water, it could not revolve
in less than 1.5 seconds, neither could a wheel
of 16 feet diameter revolve in less than 3 se-
conds; but though it is impossible for a wheel
to move as fast as the stream which turns it, yet,
if their velocities bear the same ratio to the
time of the fall through their diameters, the
wheel 16 feet in diameter may move twice as
fast as that of 4 feet.
L
2
Height of the
Time of falling,
fall, in feet.
in seconds.
TABLE VIII.

Height of the
fall, in feet.
Time of falling,
in seconds.
1
.25
14
.935
2
.352
16
1
3
.432
20
1.117
.5
24
1.22
.557
25
1.25
6
.612.
30
1.37
7
.666
36
1.5
8
.706
40
1.58
9
.75
45
1.67
10
.79
50
1.76
12
.864
J
-EXPERIMENTS ON WATER WHEELS. 155
When different streams of water produce
equal effects, the quantities must be inversely as
the fall. For instance, if 6 cubic feet in falling
through 4 feet produces a certain effect, 3 cubic
feet in falling through 8 feet would produce an
equal effect; or the quantity being the same,
the effect will be as the space fallen through.
The resistance afforded by mill-stones, and
other kinds of machinery, cannot be computed
from first principles. We can only ascertain
it by observations: as for example,
In a Corn-mill,
Suppose 4 cubic feet per second, applied at
the top of a wheel 12 feet high, will turn the
mill-stone a given number of times per mi-
nute, what is the resistance of the whole, at
the circumference of the water wheel?
Let the wheel revolve in 8 seconds; then will
the buckets contain as much water at once as is
delivered in 4 seconds, or half a revolution,
viz. 16 cubic feet, or 1000lb. But as this
weight is equally dispersed over one-half the
circumference of the wheel, the weight acting
at the extremity of the horizontal arm will be
less; for the diameter being perpendicular, the
centre of gravity of the circular arch will be
1
1
156
PART FOURTH.
.6366 of the radius, from the axis; therefore,
from the principle of the lever, .6366 multi-
plied by the whole weight 1000lb., gives 636.6,
the weight at the circumference, or at the end
of the horizontal arm.
EXAMPLE II.
Suppose the wheel revolves in 10 seconds,
every thing else remaining the same.
In this case, 20 cubic feet, or 1250lb. of
water is contained in the buckets, which mul-
tiplied by .6366, gives 795.7 lb. for the power
at the end of the horizontal arm.
In the above examples I have supposed that
the buckets contain their water till they come
to the bottom; and if the wheel moves from 3
to 4 feet per second, the buckets may be made
of such a form as to carry the water quite to the
bottom, provided they are large enough, when
at the centre, to hold near twice as much water
as is necessary to do the work; and if the wheel
moves faster, they will carry the water too far.
The Effects of Impulse and Gravity compared.
From the experiments contained in the Table
page 115, it appears, that the impulsive force
of a stream, is to the absolute weight of the
EXPERIMENTS ON WATER WHEELS. 157
column which impels it, as 16 to 10, or as 8 to
5, nearly; from which we may easily compare
the impulse with the gravity of a given quantity.
For example:
Let the head be 4 feet, and the area of the
sluice 1 inch; then will the velocity be 10.8
feet per second: that is, the square root of the
depth multiplied by 5.4.
The solid content of the column which im-
pels the stream is 4 feet multiplied by 1 inch
= 48 cubic inches, and its weight is 27.77 oz.
The quantity per second is 10.8 feet long, and
1 inch area, = 129.6 cubic inches, or 75 oz.
The velocity of the wheel is one-third the
velocity of the stream, 3.6 feet per second
(see page 30). And as 5:8:: 27.77 oz., the
whole weight of the column, 44.44 oz., the
impulsive force upon an object at rest. But,
the quantity being the same, the force is as the
square of the velocity with which it strikes the
wheel, in this case, equal to the difference be-
tween 10.8, the velocity of the stream, and 3.6,
the velocity of the wheel, that is, 7.2 feet per
second. Hence, As 10.8): 7.2 :: 44.44:
19.6 oz., the impelling force constantly acting
upon the wheel. Or if the velocity of the wheel
should have any other ratio to the velocity of
2
>
158
PART FOURTH.
the stream, suppose 1: 2, or that the wheel
moves half as fast as the stream; then, As
10.8° : 5.4):: 44,44 oz. : 11.11 oz., the force
acting upon the wheel.
In the Overshot.
Let the same quantity of water be thrown
upon the top of a bucket-wheel 4 feet diameter.
The quantity per second is 75 oz. If the
wheel moves as fast as before, which we will
suppose for the sake of the contrast, it will
revolve in 3.48 seconds, and will at once be
loaded with as much water as is delivered in
1.74 seconds, viz. in the time of half a revolu-
tion, therefore 75 oz. X 1.74 = 130.5 oz., the
weight constantly acting on the overshot wheel;
but as it is not all gravitating at the end of the
horizontal arm, but dispersed through a semi-
circle, we must, as before observed, multiply.
the whole weight 130.5 oz., by .6366, the dis-
tance of the centre of gravity in the semicircle
from the centre of the circle, and it gives 83
oz., equal to the effect of all the water at the
end of the horizontal arm, which is more than
four times the impulse of the same quantity.
EXAMPLE II.
Let the head be 9 feet, and area of the sluice
1 inch.
EXPERIMENTS ON WATER WHEELS. 159
=
Then, the square root of 9 x 5.4, gives the
velocity per second, 16.2 feet; and 16.2 x
12, gives the cubic inches per second, 194.4,
which multiplied by .5787 oz., the weight of
1 inch is 112.5 oz.; weight of a column 9
feet long and 1 inch square = 62.3 oz. Then,
As 5:8: 62.3 oz.: 99.68 oz., the impulse
upon an object at rest.
3
The velocity of the wheel = 16.2 = 5.4 feet
per second, which taken from the velocity of
the stream, leaves 10.8, the velocity with which
the stream strikes the wheel. Then As 16.2"
.81":: 99.68 oz.: 44 3 oz., the whole force
of the stream upon the wheel.
:
10.82:
In an Overshot.
5.4
The circumference of the wheel divided by
the velocity, gives (28.27) 5.2 seconds for the
time of a revolution, half of which multiplied
by the weight per second, gives 292.5 oz. for the
weight of water upon the wheel, when it moves
with the above velocity, which being multiplied
by .6366, gives 186.2 oz., the force exerted in
the direction of a tangent to turn the wheel.
Many have expressed their surprise that the
impulse of a given stream should be less than its
160
PART FOURTH.
gravity: here I have admitted the impulse to be
almost double the gravity, but the reason why
its effect is less does not seem very surprising.
OBSERVATIONS ON BUCKETS AND FLOATS.
If the floats of a wheel are fitted to move
'in a channel of the same curvature (provided
there was no loss of water), the effect of the
water would be the same as in a bucket-wheel.
Demonstration.
FIG. XXIX.
:
Let C B B be part of a water wheel; and let
the weight of the water in the bucket ab d=
w;
the sine of the angle B c d CA — S; C B,
the radius, = r. Then will be the force
exerted at B to turn the wheel in the direction
of a tangent.
ws
Next, if вbdв represent a curved channel in
which a float-wheel moves, then the water abd
will be supported by the channel db and float
ad. The sine of the angle which the channel
db makes with the horizon will be equal to that
of the angle Bcd, and the pressure which the
float sustains will be obtained from the property
of the inclined plane, viz. As the radius is to
the sine of the angle of elevation, so is the
EXPERIMENTS ON WATER WHEELS. 161
whole weight to that part which the float sup-
ports; or, Asr: s:: w: 205, the same as in the
bucket-wheel.
EXAMPLE I.
Let a bucket containing 100lb. of water be
at the distance of 30 degrees from the bottom,
to determine the force with which it acts on the
wheel, in the direction of a tangent?
The natural sine of 30° is .5, the radius
being 1; therefore,
100 x .5
1
50lb., the whole
force of the water whether confined in a bucket
or in the channel.
EXAMPLE II.
Suppose the bucket or float at the distance of
50 degrees from the perpendicular?
The natural sine of 50° is .766, which mul-
tiplied by 100, the weight of the water, gives
76.6lb. for the force; and so for
any other.
From which it appears that there is no dif-
ference, except the loss of water in the float-
wheel, for, however well it may be executed,
some water will pass; nevertheless, when the
stream is large, a wheel with floats may be found
more convenient than one with buckets. For
example, suppose a stream flowing over a dam
to be 6 feet wide, and 1 foot deep; the quan-
Y
T-
162
PART FOURTH.
tity per second would be 21 cubic feet (see page
109). Suppose 3 buckets or floats pass the
stream in 1 second, there will be 7 cubic feet
for every bucket or float. In a float-wheel there
ought not to be more than six-eighths of the
space filled with water; and in a bucket-wheel
little more than one-half. The buckets, there-
fore, ought to contain about 14 cubic feet each,
when at the end of the horizontal arm; and
the space between the floats ought to be large
enough to contain about 10 cubic feet; in which
case, if the floats are 15 inches distant, they
ought to be 16 inches deep. But for the buck-
et-wheel, the shrouds would be near 2 feet deep
if large enough to contain the water. In which
case, a float-wheel ought to be preferred; and
if a wheel is occasionally in back-water, floats
are not so much retarded as buckets.
Experiments with Wheels acted on by Impulse only.
In addition to the experiments made on buck-
et-wheels, in which the water produces the ef-
fect by its gravity, I shall add a few made with
float-wheels, on which the water acts by impulse
only. If the wheel is confined in a channel,
after the water has struck the float, it is re-
tarded, and heaped against the float; in which
case, the water is acting by impulse and gravity
combined. In order to ascertain, as near as
EXPERIMENTS ON WATER WHEELS. 163
possible, the true effect of the impulse, the fol-
lowing experiments were made. The theory
(page 30) assigns no more than a comparative
force to the water; or, if a given quantity issues
with a given velocity, the effect produced
should be as the square of the velocity with
which it strikes the wheel, and will of conse-
quence vary with the velocity of the wheel;
and the velocity of the wheel will also vary
with the resistance. The effect of the stream
will be greatest when it strikes the floats in a
perpendicular direction, and will diminish as
the obliquity increases; and as the greatest force
is exerted on the first float, it was necessary, in
these experiments, to fix the floats a little in-
clined to the circumference of the wheel, or
instead of the common direction c s, (Fig.
XXXI) to direct them to the circumference of
a circle bb, in the direction b s, so that the di-
rection of the stream may be nearly perpendi-
cular to the first float s b, which is acted upon
till another intercepts the stream, during which
time its position is constantly changing.
The velocity of the stream was 9.3 feet per
second. The weight of water per minute was
10lb. The diameter of one wheel is 12 inches;
but I take the circumference of that part of the
floats which was struck by the water to be 2.8
164
PART FOURTH.
feet, and the circumference of the other at 4.4
feet. The axle was truly turned, and sup-
ported on friction wheels, and by 41 revolu-
tions raised a weight through 5 feet.
Experiments with the 12 inch Wheel.
TABLE IX.

Experiments.
- Weight raised,
in ounces.
Time of rising,
5 feet.
Velocity of the
CoWeight, in feet,
per minute.
Velocity of the
wheel.
Velocity with
which the wheel
is struck.
Effect, by
experiment.
Effect,
computed.
Ratio of expe-
rimental effects.
12 3
1.
2.
3.
4.
5.
6.
7.
8.
10
17 30
28 33
3835
4 9 37
3.83 5.47 70 113.6 114.3
9.09 3.45 5.85 72.72 118.05
8.57 3.36 72.8118.8
118.7.
118.9
8.11 3.16.2 72.9
6.2 72.9 |119.16 119.16
59397.6 | 2.91 6.39 72.2 118.76 118
610 46 6.52 2.5 6.8 |65.2 |115.5
5.35 2.057.25 58.8107.14
711 56
106.5
96.1
Experiments with the 18 inch Wheel.
1 9 41
2 1045
3 11 47
4 12 52
5 13 54
614466
6.6
TABLE X.
7.22 4.34 4.96| 64.98| 106.61| 105.9
3.95 5.35 69.3 113.01 112.77
6.38 3.83 5:47 70.18 114.47 114.4
5.77 3.47 5.83 72.12 117.9 117.5
5.55 3.34 5.96 72.22 118.6 117.65
4.54 2.73 6.57|65.83 117.79 107.3
While the 12 inch wheel makes 41 revolu-
tions, the part of the float which is struck
passes over 115 feet, and the same part of the
18 inch wheel moves 180.4 feet: hence the ve-
locity per second is found as follows: in expe-
riment 1, As 30": 115 feet :: 1″: 3.83 feet, &c.
EXPERIMENTS ON WATER WHEELS. 165
The velocity with which the stream strikes.
the wheel is also known, by subtracting the
velocity of the wheel from that of the stream;
as in the first experiment, 3.83 taken from 9.3,
leaves 5.47. for the velocity with which the
wheel is struck.
Also, As 30" 5 feet: 60: 10 feet, the
space passed over by the weight in one minute;
which space multiplied by the weight, gives
the effect contained in the sixth column.
The greatest effect produced by the 12 inch
wheel is in the fourth experiment, where 9
ounces is raised through 8.11 feet in a minute;
their product is 72.9 for the maximum.
But the maximum in the 18 inch wheel is in
the fifth experiment, where 13 ounces is raised
5.55 feet in a minute, and their product is 72.2,
which is not quite so much as that of the less
wheel; and, indeed, the difference would have
been greater if the wheels had been equally
heavy, but the larger wheel weighs 12 oz. and
the smaller 1lb. 14 oz. It may also be observed,
that the larger wheel is in this experiment
rather short of the maximum, its velocity is
3.34 instead of 3.1, and in the next experiment
it moves too slow, or is decreasing in power.
166
PART FOURTH.
To compare the power with the effect. We
have 10lb. or 160 oz. of water falling through
2.2 feet in one minute; their product, 352, is
the effect is 73, or 7 of the power
206 But in the overshot (see page 144) the
the
power;
1000
73
power is to the effect as 18: 12.675, or as 1:
.704, or the effect is of the power, which
700
is 3.4 times as much as by impulse, though in
these experiments we have the advantage of
friction-wheels, which were wanting in the ex-
periments with the overshot; besides, the over-
shot was encumbered with a fly, without which
the motion would not have been regular.
We may further observe, that the effects ob-
tained by multiplying the square of the velo-
city with which the water strikes the wheel, by
the velocity of the wheel, as contained in the
seventh column of the Table, agree, as near
as can be expected, with the experiments, till
we come at a maximum; after which, the effect,
as found by experiment, varies from that com-
puted by the square of the velocity; and before
this, the weights raised are nearly as the squares
of the velocities with which the wheel is struck.
To
compare which, the eighth column is added,
and is found by proportion. For as the seventh
is only comparative, if we say, beginning with
the maximum, Experiment 4th, Table 9th, As
EXPERIMENTS ON WATER WHEELS. 167
Number.
Weight raised,
in ounces.
72.9, the real effect, is to 119.16, the relative
effect, so is 72.8 to 118.9, the relative, &c.; by
which process, the eighth column is formed
from the experiments, in order to compare
them with the theory.
ON UNIFORM VELOCITY.
A wheel turned by the weight or impulse of
water has its velocity increased till the resis-
tance becomes equal to the accelerating force.
The resistance may be of various kinds; and
in many cases it may be not only difficult, but
impossible to bring it into a computation. See
page 155. In the present observations, I shall
consider the resistance as arising from the
weight of the wheel, and a weight to be raised
by a cord fixed to its axle.
The following experiments were made with
a bucket-wheel 20 inches in diameter, and sup-
ported on friction-wheels: the circumference
of its axle 9 inches; the whole weight of the
wheel and axle 8lb.; the centre of gyration is
at 8.4 inches; and the resistance, at the dis-
tance of 10 inches, will be about 92 ounces.
TABLE X.

Resistance of
the wheel.
The whole
resistance.
m
9
1
2
4.5 3.5 oz
8.5 2.35
3 12.5 1.54
4 16.5 .98
5 20.5 .7
6 24.5 .52
P
8 oz.
t
V
13 2.48 2.89 2.68
10.85 16 2.03 2.12 3.28
14.04 214 | 1.55 1.63 4.3
6.35
17.48 27 1.241.30 5.37
21.2 32
25.02 37
1.05 1.07
.901.92 7.4
Time of rising
5 feet.
Velocity of the
wheel, in feet,
per second.
Velocity, by
computation.
Ounces of water
on the wheel.
168
PART FOURTH.
In the first experiment, the water-wheel re-
volves 6.7 times in 13 seconds, and raises 4
ounces through 5 feet; the velocity of the cir-
cumference is 2.48 feet per second.
In the second experiment, the wheel makes
the same number of turns in 16 seconds, and
raises 8 ounces through the same space, &c.
We are next to inquire, what weights applied
to the axle would turn the wheel, and descend
through 5 feet in 131, 16, 21, &c. seconds
(See Theo. 4, page 125). We have given,
F = 5 feet, the space passed over by the weight.
m = the weight suspended from the axle.
w = 92 oz., the weight of the wheel multiplied
by the square of the centre of gyration,
and divided by the square of its radius.
s = 10 inches, the radius of the wheel.
r = 1.42 inches, the radius of the axle.
t = the time of descent.
d=16, the feet fallen through by gravity, in
one second.
Then we have the weight m =
Fws2
dr² 42
Fr2
7.02 oz., when t 13
seconds; but when
t = 16½, m = 4.7 oz. &c.
Now, if 7 oz. falls
through 5 feet with an accelerated velocity, by
the laws of falling bodies, it would, at the end
EXPERIMENTS ON WATER WHEELS. 169
of the time, have acquired a velocity which, if
equable, would carry it over 10 feet in the same
time. And the whole effect is equal to what
half the weight would produce in passing over
the same space in the same time, with an uni-
form velocity. Half the weights found by the
above theorem are placed in the second co-
lumn, under q, which being added to the weight
raised, gives the whole resistance, as in the
next column.
To find the Quantity of Water upon the Wheel.
If the quantity delivered in one second be
multiplied by the seconds in which the wheel
makes half a revolution, the product will be
the whole quantity upon the wheel.
Or, if half the circumference, in feet, is mul-
tiplied by the quantity per second, and divided
by the velocity, the quotient will be the quan-
tity upon the wheel.
Let
the quantity per second.
c = half the circumference.
v = the velocity of the circumference.
m+q=p = the sum of the weight
and resistance.
Then will = the quantity upon the wheel,
QC
v
which quantity will vary with the velocity.
Z
170
PART FOURTH.
pr
8
= the
power applied at the circumference,
which will balance m+q, when in motion.
Hence, ec
pr QCS vpr -the efficacious
V
8
VS
moving power; and the resistance is +w+
pr.2
Qcs² + wvs² + pʊr²
vs²
QC
v
; by which divide the
moving power, and we have
Qcs² vprs
Qcs²+wvs² + por²
for the accelerating force, which, when the mo-
tion becomes uniform, must be equal to the re-
tarding force, which will be expressed by ÷w
prs
s²w + r²p
pr
S
; from which we find v =
+ pr²
=
QCS
2pr
X
s²w + pr² —prs
s²w + pr²
- Qcs
2pr
X 1-
prs
ws² + pr²°
The value of v found by the theory, may
next be compared with what it is in the expe-
riment, in which we have given Q =2 oz.,
a = 2 feet, the rest of the notation as above,
except p, which is different in every experiment.
In the first experiment p = 8, QCS
8, and
2pr
66.66
=2.934; and 1
prs
22.72
ws² + pr²
= .987,
which multiplied by 2.934,
gives 2.897 v.
In the second, p = 10.85, and v = 2.12, as
in the table; in which it appears, that the ve-
locity found by computation is, in every expe-
EXPERIMENTS ON WATER WHEELS. 171
·
riment, something too much: but the differ-
ence is less than could be expected, when we
consider the degree of accuracy which is re-
quired in the quantity of water, the weight,
diameter, inertia, friction, &c.
When half the buckets are equally loaded
with water, and the wheel at rest; if the whole
weight of the water is multiplied by .6366,
the product is the weight which, if suspended
from the end of the opposite horizontal radius,
would balance the whole. But, as near as I
can discover by experiment, when the wheel is
in motion, the effect is nearly the same as if all
the water in the buckets gravitated on the end
of the horizontal diameter. If this is true, it
may be owing, in part, to the velocity which
the water has when thrown upon the wheel, and
to the centrifugal force, by which it endeavours
to move in a tangent to the wheel. But, in
making computations, to be on the safe side,
it will be better to multiply the quantity by
.6366.
When the resistance is irregular, as in forges,
tilts, saw-mills, rolling-mills, &c. it becomes
necessary to add a fly, in order to preserve, as
near as may be, an equable motion, and to
avoid sudden shocks in the work.
172
PART FOURTH.
1
Where there is convenience, a large fly
ought to be preferred. For if a fly of 10, and
another of 40 feet diameter, revolve in the
same time, the smaller must be 4 times as heavy
as the other to produce the same effect.
In page 144, 5lb. is raised 6 feet in 142 se-
conds, or through 21 inches, the diameter of
the wheel, in 42 seconds, in which time 7lb.
of water descends through the same space;
hence, two-sevenths of the whole is employed
in overcoming the friction, resistance, &c., and
the power is to the effect as 7 to 5.
In the sixth experiment of the last Table,
24.5 oz. is raised through 5 feet in 37 seconds,
or through the diameter of the wheel in 12.95
seconds, in which time 34.5328 oz. of water
descends through the same space; and As 24.5
: 34.5328: 57.03, so is the effect to the
power, the same as above, nearly. If more
water is applied, the velocity is increased; but
in the same wheel, the ratio of the power to
the effect will always be nearly the same, at a
maximum.
;
Ender.
A.
AIR, its resistance, 125, 127.
Angular velocity, the same under what circumstance, 36.
Application of water to wheels, 134, 138.
B.
Buckets and floats compared, 160.
C.
Centre of gravity, what, 46-problems concerning, 32,
35, 48.
of gyration, 43-problems concerning, 44, 45.
of oscillation, 49, 67.
Centrifugal, and centripetal force, what, 2-problems con-
cerning, 7, 19,-when equal in different wheels, 9.
Circular motion, a machine for making experiments on,
122—experiments thereon, 136, 142,-quantity pro-
duced by a given power, 37.
D.
Different quantities of water, their effects, 145, 146.
E.
Experiments on the velocity of effluent water, 100, 105.
on the impulsive force of water, 114, 115.
on emptying of vessels, 116-with syphons,
118.
on the velocity with which water ascends into
a vacuum, 119.
on circular motion, 126, 131.
INDEX.
Experiments on the application of water, 134.
on the velocity of wheels, 138-with different
quantities of water, 145,
on the size of wheels, 148.
on the fall of water, 152.
on impulse and gravity, 156.
F.
Floats and buckets compared, 160.
Fall of water, 152, 156.
Force of a moving bar, how computed, 43.
Friction, 155.
G.
Grinding stones, their velocity, &c. 9.
Gyration, centre of, how found, 43, 44, 64.
I.
Inclined plane, ascent of bodies thereon, 21.
Initial velocity of a machine, &c. 20, 37, 57, 59, 60, 63.
Impulse of water, 112-experiments thereon, 114.
Impulse and gravity compared, 156, 159.
L.
Lever, its greatest effect, demonstrated, 24-problems
concerning, 32, 33, &c.
M.
Machine for circular motion, 122.
for measuring the force of a stream, 114.
Methods of computing the force of moving bodies, 24.
Momentum of a moving bar, 33.
0.
Oscillation, centre of, 49, 55, 67.
P.
Percussion, centre of, what, 49, &c.
INDEX.
R.
Resistance of the air, 125, 127.
of machines, 155.
S.
Steam engines, theory of, 85, 95.
Syphons, experiments with, 118.
T.
Time of emptying vessels, 116.
V.
Vacuum made by water, 121.
Velocity of water through thin plates, 100-through cones,
101-how measured, 99—through notches, 104, 109,
—into a vacuum, 119, 120.
of water-wheels, 107-when different quantities
of water are applied, 18, 19, 145-quantity commu-
nicated to a wheel by a given power, 36, 42, 58, 67.
angular, the same under what circumstances, 36.
W.
Water, how best applied to wheels, 134, 138-effects of
different quantities, 145, 146-its velocity through
syphons, 118-its velocity obtained by emptying ves-
sels, 116.
Wheels driven by impulse, their maximum, 30, 162-what
magnitude to prefer, 148, 151-their velocity, which
best, 138, 145.
Wheel and axle, its maximum, at the end of a given time,
23, 67—at the end of a given space, 74, 78, 79.
FINIS.
f
PRINTED BY 6. F. HARRIS'S WIDOW AND BROTHERS,
WATER-STREET, LIVERPOOL.
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