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 THE LIBRARY 
 
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 THE UNIVERSITY 
 OF CALIFORNIA 
 
 LOS ANGELES 
 
 GIFT OF 
 
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 Wings of War 
 
 An Account of the Important Contribution 
 of the United States to Aircraft 
 Invention, Engineering, Develop- 
 ment and Production during 
 the World War 
 
 By 
 
 Theodore Macfarlane Knappen 
 
 With an Introduction by 
 Rear-Admiral D. W. Taylor 
 
 Chief Constructed. U. S. N. 
 
 With 43 Illustrations 
 
 G. P. Putnam's Sons 
 
 New York and London 
 
 vibe fmfcfcerbocfcer press 
 
 1920 

 
 COPYRIGHT. 1920 
 
 BY 
 THEODORE M. KNAPPEN
 
 Mathematical 
 Science- 
 
 
 PREFACE 
 
 THE manuscript of this book was written in 1919. 
 The numerous Congressional investigations of the 
 management of the war which have taken place 
 since the writing have revealed many shortcomings 
 in both the army and navy that were concealed 
 during the conflict period and aircraft produc- 
 tion is no longer singled out for a monopoly of hos- 
 tile criticism and sweeping condemnation, as it was 
 in the unhappy days when its managers were seek- 
 ing to accomplish the impossible. Time is a great 
 adjuster of judgments as well as a healer of wounds, 
 and it is the writer's belief that the ultimate ver- 
 dict of history will virtually coincide with the 
 conclusion reached in the following pages that in- 
 stead of being, as was once universally believed, 
 the outstanding industrial fiasco of America's part 
 in the World War, the aircraft achievements de- 
 serve to rank with any of those of our "second line 
 of defense," which, taken as a whole, were highly 
 creditable. 
 
 iii
 
 iv Preface 
 
 The war happily came to an end too soon for 
 our huge industrial conversions and mobilizations 
 to enjoy the spectacular triumph that would have 
 been theirs in the spring of 1919. Nevertheless, 
 the knowledge of the Central Empires that a 
 country that was as innocent of knowledge of 
 the art of making military aircraft in the spring 
 of 1917 as it was before the Wright Brothers 
 made their first flight in a heavier-than-air ma- 
 chine, was, in the fall of 1918, producing air service 
 engines in greater volume than all the rest of the 
 Allies together, with a similar preeminence in the 
 production of 'planes rapidly approaching and a 
 magical expansion of all related productivities, had 
 its certain and conclusive though undramatic effect 
 on the moral and mental processes that led to the 
 collapse of Germany before the death-blow was 
 delivered. 
 
 T. M. K. 
 
 WASHINGTON, D. C. 
 May i, 1920.
 
 INTRODUCTION 
 
 THE story of the United States army aircraft 
 production program is essentially a story of con- 
 fident hopes, bitter disappointments, failures, and 
 successes such as inevitably attend the creation 
 from nothing of an immense industrial organiza- 
 tion. The existing publications which give the 
 history of this undertaking are largely the volumi- 
 nous reports of congressional and other investi- 
 gating committees which throw into strong relief 
 all failures and unfortunate circumstances, and 
 gloss over with very scant mention the successes 
 and the fortunate circumstances. For this reason, 
 it is especially desirable that a less one-sided ac- 
 count of the army air effort be published, and, 
 hence, I am glad to see the appearance of this book. 
 
 The conception of a tremendous air program, 
 and the courage to undertake it in spite of the ob- 
 vious difficulties is, in my opinion, due to General 
 Squier and Colonel Deeds, and, since these offi- 
 cers have received public criticism for any and all 
 shortcomings in the program, it is no more than
 
 vi Introduction 
 
 fair that they should also receive the credit for the 
 wonderful success of other parts of the program. 
 
 The entire American aviation program centered 
 in the conception, development, and production of 
 the Liberty motor, and this I consider one of the 
 outstanding achievements of the War. The army 
 staked much on the Liberty engine, but the navy 
 staked everything. The navy, in fact, for its 
 service 'planes adopted a 100% Liberty motored 
 program, calling for a series of large flying boats 
 engined with one, two, or three Liberty motors. 
 This program was adopted by the Navy Depart- 
 ment before the Liberty motor was fully proved. 
 It is of interest to record the fact that the first 
 Liberty motor to fly was mounted in a naval sea- 
 plane, the first twin Liberty motors were flown in 
 a naval seaplane, and, finally, the Atlantic was 
 crossed by four Liberty motors in a naval seaplane. 
 
 Since the navy relied upon the army for its 
 Liberty motors upon which its program was based, 
 and since the army delivered the goods in this 
 respect so that the navy program was not delayed a 
 day by failure to have those wonderful motors ready 
 when the navy 'planes were ready for their in- 
 stallation, it is natural that those of us in the navy 
 who had to struggle with the production of 'planes 
 should have in our hearts a warm spot for our
 
 Introduction vii 
 
 brothers in the army who conceived and pro- 
 duced, with such astonishing success, the Liberty 
 motor. 
 
 The history of the navy's aircraft production 
 program has not been covered by the proceedings 
 of investigating committees. The navy's problem 
 was undertaken successfully with the existing 
 naval industrial organization. The navy was, 
 therefore, spared the tribulations incident to or- 
 ganizing a brand new industrial machine, tribula- 
 tions which are little understood or appreciated by 
 the layman. Also, the navy's problem was of less 
 difficulty than the army's because not on such a 
 gigantic scale. The navy entered the war with 
 an existing shipbuilding organization, provided 
 with aeronautical engineers, wind tunnel research 
 facilities, training seaplanes and airships, and an 
 adequate training station. 
 
 The naval program of service 'planes was adopted 
 in the fall of 1917, and was never changed except 
 to be increased twice as to numbers. Produc- 
 tion was going ahead with full volume in the 
 spring of 1918, and, by September, 1918, all fifteen 
 naval air stations abroad, as well as our own 
 coast-patrol stations, had been shipped full com- 
 plements of service 'planes. Shipments were then 
 stopped, and steps taken to slow production. The
 
 viii Introduction 
 
 armistice came before shipments abroad had to 
 be resumed. "Happy the people whose annals 
 are uninteresting." 
 
 D. W. TAYLOR, 
 Rear Admiral (C.C.), U.S.N., 
 Chief of Bureau of Construction and Repair. 
 
 WASHINGTON, May, 1920.
 
 CONTENTS 
 
 CHAPTER PAGE 
 
 I. THE TASK SET BEFORE THE BUILDERS i 
 
 II. BEFORE THE WAR . . . 7 
 
 III. THE BEGINNING .... 14 
 
 IV. MAKING UP FOR LOST TIME . 22 
 
 V. SEEKING GUIDANCE . . . 33 
 
 VI. TRAINING, 'PLANES AND ENGINES . 39 
 
 VII. THE BOLLING COMMISSION AND FOREIGN 
 
 ASSISTANCE . . .51 
 
 VIII. ORIGIN OF THE LIBERTY ENGINE . 63 
 
 IX. BIRTH OF THE LIBERTY ENGINE . 76 
 
 X. MAKING THE FIRST LIBERTY MOTORS 85 
 
 XI. LIBERTY ENGINE PRODUCTION . 102 
 
 XII. INCIDENTS OF LIBERTY ENGINE PRO- 
 DUCTION 116 
 
 XIII. DEVELOPMENT AND PRODUCTION OF 
 
 ENGINES OTHER THAN THE LIBERTY 122 
 
 XIV. CENTRALIZATION OF MANUFACTURING 
 
 RESPONSIBILITY . . . .132 
 
 XV. THE WRESTLE WITH THE 'PLANES . 144 
 ix
 
 Contents 
 
 XVI. THE PROBLEM OF THE NIGHT-BOMB- 
 ING MACHINES . . . .162 
 
 XVII. AIRPLANE PRODUCTION RESULTS . 171 
 XVIII. THE STRIVING FOR SPRUCE . .174 
 
 XIX. DEVELOPMENT AND PRODUCTION OF 
 
 DOPE AND COTTON FABRIC . 181 
 
 XX. MACHINE GUNS FOR AIRCRAFT . 189 
 
 XXI. RADIO TELEPHONE AND AERIAL PHO- 
 TOGRAPHY IN CONNECTION WITH 
 AERIAL OBSERVATION, THE CHIEF 
 FUNCTION OF MILITARY AVIATION 197 
 
 XXII. AIRPLANE BOMBS, AERIAL PYRO- 
 TECHNICS, AND AVIATORS' PER- 
 SONAL EQUIPMENT, ETC. . .215 
 
 XXIII. MILITARY BALLOONS . . . 225 
 
 XXIV. TRAINING FIELDS, CAMPS, AND 
 
 SUPPLY . . . . 238 
 
 XXV. NAVAL AIRCRAFT PRODUCTION . 245 
 
 XXVI. "LYNCHING THE AIRCRAFTERS" . 261 
 
 XXVIL REVIEW AND PROSPECT . . . 272 
 
 INDEX 283
 
 ILLUSTRATIONS 
 
 PAGE 
 
 THE NC 4, LIBERTY-ENGINE-DRIVEN CON- 
 QUEROR OF THE ATLANTIC, IN FLIGHT AT 
 PENSACOLA, FLORIDA. . . Frontispiece 
 
 Navy Photo 
 
 ENTHUSIASM AROUSING MEETING OF AIRPLANE 
 WORKERS IN THE HEAT OF WAR'S FEVER 26 
 
 A TYPICAL "SPEED-UP" MEETING OF AIRCRAFT 
 WORKERS ...... 42 
 
 FRENCH-MADE AMERICAN SPAD AT THE 
 FRONT ... . .; . . .54 
 
 "THE FLYING FISH," A DECORATED NIEUPORT 
 AT THE FRONT . . . . . 54 
 
 U. S. Air Service Photo 
 
 LIBERTY MOTORS UNDER THE DYNAMOMETER 
 TEST , .62 
 
 WOMAN OPERATOR MACHINING CYLINDERS OF 
 LIBERTY MOTORS (AT THE CADILLAC PLANT, 
 DETROIT). THE WAR EMERGENCY NECESSI- 
 TATED THE EMPLOYMENT OF THOUSANDS OF 
 
 WOMEN IN THE AIRCRAFT INDUSTRY . . . 88 
 
 PACKARD MOTOR CAR COMPANY PLANT AT 
 DETROIT. ORIGINAL PLANT AND EMERGENCY
 
 xii Illustrations 
 
 PAGE 
 
 EXTENSION, DEVOTED LARGELY TO LIBERTY 
 ENGINE PRODUCTION DURING THE WAR . 92 
 
 LINCOLN MOTOR COMPANY PLANT AT DETROIT, 
 RUSHED TO COMPLETION IN RECORD TIME 
 FOR MANUFACTURE OF LIBERTY ENGINES. 
 BUILDING ERECTED, ORGANIZATION OF 6,000 
 PERSONS CREATED, AND 2,000 LIBERTY 
 MOTORS PRODUCED, ALL IN TWELVE 
 MONTHS 92 
 
 ASSEMBLING LIBERTY MOTORS AT THE PLANT 
 OF THE LINCOLN MOTOR Co. . . .106 
 
 SECTION OF TRACK SYSTEM FOR MACHINING 
 UPPER HALF OF LIBERTY MOTOR CRANK 
 CASE, LINCOLN MOTOR Co. * . . 106 
 
 AT WORK ON LIBERTY ENGINE PARTS AT THE 
 PACKARD PLANT . . ,. ,.114 
 
 A CURTISS TRAINING PLANE AT KELLY 
 FIELD * . 136 
 
 U. S. Air Service Photo 
 
 ELMWOOD PLANT OF THE CURTISS AEROPLANE 
 AND MOTOR CORPORATION, BUFFALO, NEW 
 YORK, ERECTED EXCLUSIVELY FOR WAR 
 AIRPLANE WORK, AND EMPLOYED 15,000 PER- 
 SONS 136 
 
 INSTALLING LIBERTY ENGINES IN DH-4's AT 
 THE DAYTON-WRIGHT PLANT . . .144 
 
 GENERAL ARRANGEMENT OF THROTTLE AND 
 GAS CONTROL, AND OTHER INSTRUMENTS IN 
 PILOT'S COCKPIT OF A DH-4. THE NUMER-
 
 Illustrations xiii 
 
 ous INSTALLATIONS IN A LIMITED SPACE WERE 
 A HARD PROBLEM FOR THE DESIGNERS . 146 
 U. S. Air Service Photo 
 
 MAKING AIRPLANE WINGS . '. . . .150 
 
 BIRD'S-EYE VIEW OF THE DAYTON-WRIGHT 
 AIRPLANE COMPANY'S PLANT AT MORAINE, 
 NEAR DAYTON, OHIO . . . .150 
 
 A LOENING MONOPLANE ON THE GROUND . 158 
 
 U. S. Air Service Photo 
 
 LOENING MONOPLANE IN FLIGHT IN THE 
 CLOUDS . . . . -. . .158 
 
 GENERAL PEYTON C. MARCH, CHIEF-OF-STAFF, 
 PRESIDENT AND MRS. WILSON, INSPECTING 
 HANDLEY-PAGE BOMBER AT WASHINGTON. 
 SMALL SINGLE-SEATER AT RIGHT . .162 
 U. S. Air Service Photo 
 
 THE HAVILAND 9, SUCCESSOR TO THE DH-4 164 
 
 THE FIRST AMERICAN-BUILT LIBERTY- 
 CAPRONI 164 
 
 GLENN MARTIN BOMBER WITH Two LIBERTY 
 ENGINES . . . . . . . 170 
 
 U. S. Air Service Photo 
 
 CURTIS JN 4 TRAINING PLANE, SHOWING MAR- 
 LIN MACHINE GUN AND PART OF SYNCHRONIZ- 
 ING DEVICE ...... 190
 
 xiv Illustrations 
 
 PAGE 
 
 OBSERVER'S SEAT IN DH-4, SHOWING LEWIS 
 MACHINE GUNS ON UNIVERSAL MOUNT . 200 
 U. S. Air Service Photo 
 
 VIEW OF OBSERVER'S COCKPIT IN DH-4, SHOWING 
 GENERAL ARRANGEMENT OF APPARATUS, IN- 
 CLUDING WIRELESS SENDING AND RECEIVING 
 OUTFIT, AND SCARFF MOUNTS FOR LEWIS GUNS 206 
 
 A COMPLETELY EQUIPPED DE HAVILAND 4, 
 SHOWING BOMB RACKS UNDER LOWER WING, 
 AND FORE AND AFT MACHINE GUNS . 216 
 
 U. S. Air Service Photo 
 
 AVIATOR'S OXYGEN MASK IN POSITION, READY 
 FOR USE . . . . . . . 220 
 
 FILM FROM MACHINE-GUN CAMERA SHOWING 
 "SHOTS" . . . . . 222 
 
 A NAVY "BLIMP" NON-RIGID DIRIGIBLE IN 
 THE AIR . ... . . . 226 
 
 6-CYLINDER, IOO-H. P. REAR WINDLASS ENGINE 
 CATERPILLAR, TRACTOR ADAPTER, FOR TOW- 
 ING AND CONTROLLING OBSERVATION BAL- 
 LOONS . . . . , . . . 230 
 
 CAQUOT "SAUSAGE" BALLOON, BEGINNING ITS 
 ASCENT 230 
 
 U. S. Air Service Photo 
 
 A UNIT ASSEMBLY ROOM IN THE B. F. GOOD- 
 RICH COMPANY'S BALLOON PLANT AT AKRON, 
 OHIO . . . . . . . -234 
 
 U. S. Air Service Photo
 
 Illustrations 
 
 XV 
 
 PAGB 
 
 CAPTURED CAQUOT "SAUSAGE" BALLOON . 240 
 
 PARTIAL VIEW FROM THE AIR OF THE VAST 
 AMERICAN AIR SERVICE ASSEMBLY REPAIR 
 AND SALVAGE SHOPS AT ROMORANTIN, 
 FRANCE . . . . . . . 244 
 
 U. S. Air Service Photo 
 
 HULLS OF F-5-L TYPE SEAPLANES. CURTISS- ^ 
 ELM WOOD PLANT, BUFFALO . . . 250 
 
 U. S. Air Service Photo 
 
 FINAL ASSEMBLY OF FLYING BOATS AT CURTISS 
 PLANT, ELMWOOD, BUFFALO . . . 250 
 
 U. S. Air Service Photo 
 
 CAPTAIN K. G. PULLIAM, JR., AND His 15- 
 METER, DECORATED NIEUPORT PLANE, "THE 
 JAZBO" .1 252 
 
 AMERICAN-MADE HANDLEY-PAGE BOMBER WITH 
 SINGLE-SEATER AT LEFT .... 252 
 
 PARTIAL VIEW OF THE GREAT A. E. F. AIR SER- 
 VICE TRAINING SCHOOL AT ISSOUDUN, 
 FRANCE . . . . . . . 260 
 
 U. S. Air Service Photo 
 
 TUNING UP A SPAD IN A FIELD HANGAR AT THE 
 FRONT . . . . . . 260 
 
 U. S. Air Service Photo 
 
 I48TH AMERICAN AERO SQUADRON AT THE 
 FRONT, AT PETITE-SYTHE, FRANCE, EQUIPPED 
 WITH SOPWITH-CAMEL PLANES . . . 276 
 
 U. S. Air Service Photo
 
 WINGS OF WAR 
 
 CHAPTER I 
 
 THE TASK SET BEFORE THE BUILDERS 
 
 THE entire air force of the United States of 
 America broke down and disappeared in the tri- 
 fling contest with the Mexican bandit, Villa, in 
 1916. A year later the nation whose air forces and 
 material were so pitifully small that they were 
 unable to cope with the reconnaissance problems 
 offered by the activities of a Mexican bandit was 
 called upon to plunge into the greatest aircraft 
 production program and into the training and 
 organization of the largest flying personnel the 
 world had seen. 
 
 It was almost as if some armorer of the feudal 
 ages, after making his first arquebus, had been 
 called upon to make modern rifles by the millions. 
 Or, as if the artificers who cast the fifteenth-cen- 
 tury "mystery" guns that conquered Constanti-
 
 2 Wings of War 
 
 nople and crushed the Byzantine Empire for the 
 Turk had in a moment been ordered to produce 
 the fifteen-inch guns of a modern battleship or 
 fortress. 
 
 We knew nothing, one might say, of aircraft ; and 
 we were required to know all. We had done 
 nothing ; and it was demanded of us that we should 
 do all. We had altogether of every kind and des- 
 cription, when the war with Germany came, some 
 60 planes all told. In the preceding year we had 
 ordered 366 machines, had succeeded in getting 64 
 delivered, and so great was this task for our manu- 
 facturers that they had asked to be relieved of 
 most of their contract obligations. They had tried 
 to build 366 airplanes in a year and confessed to 
 an 80 per cent, failure. 
 
 We lacked aeronautical engineers, we lacked 
 large plants, we lacked skilled workmen, and, 
 although the war in Europe had been raging for 
 almost three years, we lacked absolutely knowledge 
 of aeronautical military requirements. In fact we 
 had not built a single land combat plane of any 
 description either for ourselves or the Allies. We 
 were as ignorant as a child unborn of the nature of 
 the equipment of a military 'plane. 
 
 Suddenly we plunged all unprepared into the 
 war and with a unanimous voice the Allies and our
 
 The Task Set before the Builders 3 
 
 own people declared that perhaps our greatest con- 
 tribution to the war would be such vast numbers 
 of airplanes that the German army would be 
 blinded and the whole German Empire overhung 
 with a cloud of hostile airplanes. Almost gayly in 
 our ignorance we undertook within three months 
 after the declaration of war a program calling for 
 the completion within one year of 22,500 'planes. 
 We proposed to manufacture and maintain at the 
 front 4500 machines. At this time France and 
 England between them, after many years of prepa- 
 ration and three years of active combat, had been 
 able to maintain at the front not more than 2000 
 combat machines. Had it not been for our blissful 
 ignorance of the magnitude and complexities of the 
 task, we would never have undertaken it. We 
 were fools, rushing in where angels feared to tread. 
 Yet if we had not undertaken so much we would 
 not have done as much as we did. Had it not been 
 for our optimism and our sublime confidence we 
 would have undertaken little and accomplished less. 
 The impossible was undertaken and its accom- 
 plishment was glowingly foretold; it was not 
 achieved but the spirit that dared so much and 
 predicted so much was the spirit that made it pos- 
 sible actually to do so much. 
 The task was of such unparalleled magnitude and
 
 4 Wings of War 
 
 so bewildering in its complexity that the men who 
 undertook to carry it through were only able to 
 stimulate themselves for the stupendous work by 
 dwelling on its colossal proportions as something 
 that they must and would overcome, without reflect- 
 ing overmuch on the relations between its dimen- 
 sions and the caliber of the instrumentalities with 
 which it was to be accomplished. They refreshed 
 themselves for the daily effort against the awesome 
 job by the continual contemplation of it as a thing 
 accomplished. They lived and worked in a sort of 
 dream of mighty deeds that must be done. They 
 were self -hypnotized and ofttimes spoke and acted 
 as if the will to do was the thing done. Their 
 enthusiasm and confidence were communicated to 
 all who were associated with them. Everybody 
 undertook the impossible and was sure it could 
 be done. Manufacturers who had never built an 
 airplane engine contracted to produce them more 
 rapidly and in greater volume than the greatest 
 builders of Europe would have dreamed of. Opti- 
 mism reacted on optimism, confidence was ex- 
 panded by answering confidence. Thus arose a 
 sort of dreamland of herculean effort united 
 with an illusory sanguineness, out of which 
 came magnificent courage, wonderful audacity, 
 and almost superhuman achievements, which
 
 The Task Set before the Builders 5 
 
 were still short of what had been confidently 
 predicted. 
 
 The aircrafters were judged not by what they 
 did, but by what the public came to believe that 
 they could do. They went at their task as a 
 climber approaches a high mountain by looking 
 always upward to the eternal snows and pro- 
 ceeding steadily in the direction of the summit 
 without discouraging himself by visualizing the 
 intervening difficulties. Had our aircraft managers 
 and manufacturers fully realized at the start how 
 many gullies and valleys and canyons, how many 
 rough slopes, how many precipices and crevasses 
 were in their way, how much they would have to 
 go down in order to go up, before they reached 
 the summit, they would have given up in despair. 
 Looking back now in the fatigue and reaction of 
 achievement they would not dare to undertake 
 what they finally did accomplish. 
 
 In the making of almost everything else that was 
 essential to the material side of the war, America 
 was more or less experienced. We had built ships 
 before and we knew all the arts of cannon-making. 
 We were expert armorers, we were the world's 
 premier makers of rifles, and we had built vast 
 quantities of machine guns. We were the chief 
 manufacturers of military explosives. We even
 
 6 Wings of War 
 
 had the nucleus of a great army and we had a 
 powerful navy. But in the building of aircraft we 
 were as children ; yet to us was assigned the greatest 
 effort, comparatively, in that of which we knew 
 least. 
 
 Ignorant of the aerial arts, the task set for us 
 was nothing less than the conquest of the air. The 
 war was to be won in the air. All the efforts of 
 France, England, and Italy had not been sufficient 
 to produce that vast aerial armada that was to 
 encompass the German armies and the German 
 Empire above as fleets and armies had encompassed 
 them below. Ignorant as we were, our task was 
 to convert our vast manufacturing resources and 
 genius for mass production from known to unknown 
 work, do it with surpassing speed, and gain for 
 the Allies the dominion of the air.
 
 CHAPTER II 
 
 BEFORE THE WAR 
 
 THE heavier-than-air flying machine was in- 
 vented in America. It was used and applied 
 elsewhere. The Wright brothers first flew in a self- 
 propelled airplane, at Kittyhawk, North Carolina, 
 on December 17, 1902. Sixteen years later, the 
 birthland of the airplane, drawn into the vortex of 
 the very world war the Wrights believed the air- 
 plane would make impossible, when sufficiently 
 developed and multiplied, was woefully lacking in 
 knowledge of the science and art of aeronautics 
 and aircraft manufacture. 
 
 When the Germans struck their sudden and 
 treacherous blow in August, 1914, they had 1200 
 military airplanes, France had 300, England 250. 
 The United States had practically none. Three 
 years later when the war engulfed us we still had 
 practically none. There was not a man in the 
 American army who had ever flown in a fighting 
 'plane of any sort, unless possibly as a guest; 
 
 7
 
 8 Wings of War 
 
 scarcely anyone except the military observers had 
 even seen such a thing as a modern military 'plane. 
 Our little aviation section of the Signal Corps had 
 some machines but by no stretch of the imagina- 
 tion could they be called fighting 'planes. The 
 total personnel of the aviation section was 52 
 officers, noo enlisted men, and 210 civilians. 
 Probably not more than a dozen of this force were 
 expert flyers. There were not enough of them to 
 make even a respectable start in training recruits. 
 This meager body of men had at their disposal less 
 than a hundred machines of almost as many 
 types as there were machines. The government 
 whose inventive sons, the Wright brothers, had 
 given the aeroplane to the world, had during eight 
 years of mild and skeptical Congressional interest 
 in aeronautics managed to collect 54 machines and 
 had actually ordered 59. In 1916, after the war in 
 Europe had been raging with frightful and ominous 
 intensity for two years, we got around to ordering 
 366 airplanes ; but only 64 were delivered. It cook 
 the nine leading manufacturers of the country a 
 year to produce an average of five 'planes a month, 
 and most of them asked to be relieved of a part of 
 what they had undertaken to do. From the stand- 
 point of quantitative production the business of 
 aircraft manufacturing was almost non-existent in
 
 Before the War 9 
 
 the United States. There was only one 'plane 
 plant that was entitled to be called a large factory. 
 The rest were hardly more than shops some of 
 them ludicrous shops. There were many manu- 
 facturing concerns on paper and quite a number 
 had offices, but there were only six or seven that 
 had really done anything even in the small pre- 
 bellum way. 
 
 There were perhaps a dozen aeronautical engi- 
 neers in the whole country who were men of 
 marked ability and recognized achievements, but 
 not one of them was then competent to design a 
 complete up-to-date fighting aeroplane without 
 further acquainting himself with the development 
 of military aircraft in Europe. In brief, in a broad 
 way of speaking, we had neither factories, manu- 
 facturers, nor engineers. We were as helpless tech- 
 nically and industrially as we were militarily if 
 not more so. 
 
 Some manufacturing had begun of engines of 
 foreign design on orders from the Allies. Thus the 
 Wright-Martin Company, of New Brunswick, 
 N. J., had taken up the manufacture of the 
 Hispano-Suiza engine; and the General Vehicle 
 Company, of Long Island City, N. Y., had begun 
 to make some Gnome motors. The Curtiss Com- 
 pany was making its own engines, the OX and
 
 io Wings of War 
 
 the OXX, the former being of about 100 horse- 
 power for use in training machines and the latter 
 being of 200 horsepower for navy training 'planes. 
 The Sturtevant Company was building an engine 
 of 135 horsepower and the Thomas-Morse Com- 
 pany was producing an engine that was to be an 
 improvement on the Sturtevant. The Hall-Scott 
 Company was next to the Curtiss the largest pro- 
 ducer, and was making four- and six-cylinder 
 engines. The Packard Motor Car Company, the 
 Pierce- Arrow Company, the Knox Motors, the 
 Duesenberg Motors Corporation, the Union Iron 
 Works, the Wisconsin Engine Company, and 
 others were developing engines. 
 
 Among the engineers were Glen Curtiss of the 
 Curtiss Company and several associates; Orville 
 Wright; Willard of the L. W. F. and later of 
 the Aeromarine Company; Charles Day of the 
 Standard Aero Corporation; Starling Burgess of 
 the Burgess Company; Grover C. Loening of 
 the Sturtevant Company; B. D. Thomas of the 
 Thomas-Morse Company; C. M. Vought of Lewis 
 & Vought, New York City; Glenn L. Martin of 
 Los Angeles; J. C. Hunsaker of the navy; and 
 Capt. V. E. Clark of the Signal Corps. 
 
 J. G. Vincent, chief engineer of the Packard 
 Motor Car Company, had been engaged in motor
 
 Before the War u 
 
 research and development work for two years and 
 had produced several different models of 12-cylin- 
 der aviation engines of from 125 to 225 horsepower 
 with the result that he had collected a vast amount 
 of data regarding aviation engines and had gath- 
 ered around him an efficient experimental and lab- 
 oratory organization. This recent experience was 
 added to a rich experience in the designing and 
 quantity production of automobile engines the 
 sort of experience the aircraft manufacturers and 
 engineers proper mostly lacked. 
 
 E. J. Hall of the Hall-Scott Motor Car Company 
 had worked developmentally on aviation motors 
 for eight years and had got into a very considerable 
 production of a number of different types which 
 his company had delivered to the governments of 
 Russia, Norway, China, Japan, Australia, Canada, 
 and Britain. He had also completed a 12 -cylinder 
 engine of 300 horsepower, but like the Vincent 
 models it was too heavy in relation to its horse- 
 power to be suitable for military purposes. Mr. 
 Hall thus had a long and very practical experience 
 in aviation motor engineering and was familiar 
 with the problems of quantity production. 
 
 The largest order any manufacturer had ever 
 had from the United States Government before 
 1917 was 22; and the Curtiss Company, which re-
 
 12 Wings of War 
 
 ceived that, had only made a limited number of 
 training and some experimental seaplanes on for- 
 eign account. None of the manufacturers or en- 
 gineers knew much about fighting 'planes. None 
 of them had ever sent any except seaplanes to 
 Europe. No land airplane made in America had 
 ever except, possibly, experimentally carried a 
 machine gun or any but the most ordinary and 
 civilian equipment. Such things as oxygen appa- 
 ratus, radio telegraph and telephone, landing flares, 
 electric lighting apparatus, bomb-dropping devices, 
 observation cameras, special compasses, machine 
 guns adapted to airplanes, instruments for meas- 
 uring heights and speed, and many others were an 
 unopened book to American 'plane designers and 
 manufacturers. Yet their importance and the dif- 
 ficulty of designing and procuring and adjusting 
 them to the machines were so great that they after- 
 wards came directly or indirectly to be the chief 
 factor in the retardation of quantity production. 
 Had it not been for them combat 'planes would 
 have been produced in the United States on a large 
 scale several months earlier than actually was the 
 case. 
 
 This, then, was the situation of aviation and 
 aeronautical science and art in the United States 
 at the beginning of the war: only a handful of
 
 Before the War 13 
 
 experienced flyers, of whom none had real military 
 experience; only seven or eight manufacturing 
 plants that could even by courtesy be called such ; 
 not more than a dozen aeronautical engineers, and 
 none of them competent, by reason of inexperience, 
 to design a fighting 'plane; some engineering and 
 manufacturing experience in the development and 
 production of aviation engines ; no military organi- 
 zation worthy of mention ; very few workmen used 
 to the refinements of manufacture required in the 
 production of such a delicate and yet powerful 
 machine as an aviation motor. 
 
 This was the preparation with which in 1916 we 
 looked forward into the dread year that was to see 
 our entry into the tempest of the European War. 
 
 This was the domestic foundation on which reso- 
 lute men were within a few months to be called to 
 build the greatest aircraft industry in the world. 
 No proper understanding of the magnitude and 
 difficulties of their task, no measure of their degree 
 of success or failure is possible without first of all a 
 full comprehension of what they had to begin with.
 
 CHAPTER III 
 
 THE BEGINNING 
 
 THE National Advisory Committee on Aero- 
 nautics had been created by Congress in 1915 and, 
 though chiefly charged with scientific and technical 
 phases of the general development of aeronautics, 
 it began in the latter part of 1916 to collect some 
 data regarding military aviation potentialities. 
 Soon afterwards the Council of National Defense, 
 authorized by Congress in the summer of 1916, 
 began to function and established its Advisory 
 Commission which early took up aerial defense. 
 Some consideration was given to possible locations 
 for flying fields, a sort of survey of existing aviation 
 plants was made, some attempt was made to stim- 
 ulate manufacturers' interest in the production of 
 aeroplanes and engines, and a feeble effort was 
 made by the Signal Corps (which despite all its 
 efforts had received but the scantiest financial 
 support from Congress) to bring into its slender 
 organization some experience and ability drawn 
 from civil lif e. 
 
 14
 
 The Beginning 15 
 
 As the outcome of a visit of the National Advi- 
 sory Committee to Detroit in November, 1916, 
 Sidney D. Waldon, a Detroit manufacturer, who 
 had been keenly interested in aviation since 1910 
 and had been active in the Aero Club of that city 
 and in providing for aviation training in the 
 Michigan National Guard, was induced to apply 
 for admission to the Signal Corps. He did not 
 receive his commission as Captain until some time 
 in February, but in the meantime acted as a civil- 
 ian assistant. 
 
 At that time the executive offices of the aviation 
 section of the Signal Corps occupied a few rooms 
 in the Anson Mills building in Washington. 
 Capt., later Brig. Gen., William Mitchell, was then 
 Aviation Executive Assistant to Lt. Col. Geo. O. 
 Squier, later Major General, chief of the Signal 
 Corps; Maj., later Brig. Gen., B. D. Foulois was 
 in charge of the first aero squadron at San Antonio, 
 Tex., Capt. De Witt Milling was in charge of 
 engineering; Capt. Virginius E. Clarke, later Lieu- 
 tenant Colonel, was assigned to engine design 
 and W. H. H. Hutton, later Colonel, looked 
 after the records of production. There were then 
 only two flying fields controlled by the Signal 
 Corps, there were only 28 officers and 1106 men 
 in the enlisted and civil personnel. As stated
 
 16 Wings of War 
 
 above, there were less than a hundred serviceable 
 machines of any kind and as late as January i, 
 1917, the total number of machines that had been 
 made for the army from the beginning of the air 
 service was only 118. 
 
 In view of the imminence of the peril that then 
 confronted the nation, it is almost pathetic to read 
 of Howard Coffin then a member of the Council of 
 National Defense (Advisory Commission), who was 
 devoting special attention to aeronautical matters 
 and had made a preparedness industrial survey of 
 the country for Secretary Daniels of the Navy 
 and S. D. Waldon making trips to inspect the few 
 aircraft factories of the country, encouraging the 
 aeronautical exposition in New York and scratch- 
 ing on the surface of the towering mountain of 
 difficulties and tasks that were to be overcome. 
 One of these early tasks was the working out of a 
 plan whereby patent monopolies would not inter- 
 fere with a general national effort in case of need. 
 About the first order given at this time to stimu- 
 late production was one to the General Vehicle 
 Company for one hundred Gnome engines, half for 
 the army and half for the navy, at a price of #5000 
 apiece. 
 
 As showing how trivial were American official 
 aviation efforts, Mr. Waldon relates that on in-
 
 The Beginning 17 
 
 vestigation of the records he found that from 1908 
 to 1916 the army had ordered 59 'planes and re- 
 ceived 54 and that during 1916 it ordered 366 
 and received 64 so that three months before the 
 United States plunged into a war, every report of 
 which for more than two years had told of the 
 vital importance of airplanes to its successful 
 waging, the army had received altogether only 1 18 
 machines, of which many had been destroyed or 
 were obsolete. The original 54 'planes came from 
 four makers and the largest number awarded to a 
 single manufacturer in the whole eight years since 
 the Signal Corps had taken up aviation was 22. It 
 took nine factories to turn out the 64 machines 
 that were tardily delivered to the army during 1916. 
 This was the kind of support the United States gave 
 to the building-up of an industry which was really 
 as vital to national defense as the army and navy. 
 It was not until 1914 that Congress became lib- 
 eral enough to appropriate #300,000 for the pur- 
 chase of airplanes. It was in the same year that 
 five officers were sent to the Massachusetts Insti- 
 tute of Technology for a special course in aero- 
 nautics. These five men were the regular army 
 technically trained personnel with which to face 
 one of the greatest engineering tasks ever imposed 
 upon any body of men.
 
 i8 Wings of War 
 
 The situation improved little with the certain 
 approach of war and was no better for a month 
 after we declared war, except that there had been 
 a rapidly developing dismay that was to be the 
 father of enterprise and that there was a daily 
 expanding understanding of how much must be 
 done. As late as May 12, 1917, the outstanding 
 orders for 'planes for both the army and navy were 
 as small as 334, a number which was later to be 
 exceeded by the weekly production schedule of a 
 single company. 
 
 These orders were distributed between sixteen 
 actual or so-called manufacturers, and the fact 
 that most of them were never filled illustrates how 
 large a proportion the latter constituted. The 
 orders covered ten distinct types and thirty-two 
 different designs, each manufacturer being per- 
 mitted to produce about what his yearnings or his 
 ingenuity suggested. The Curtiss Company 
 then the only aeroplane manufacturing concern in 
 the country of important capacity led with or- 
 ders for 126 and their 53 R-4's were the largest 
 number of any one design, and the largest number 
 of any one type was 116 twin-engine hydroplanes. 
 There were 72 training 'planes of eight different 
 types; 85 were land reconnaissance machines of 
 four designs ; 26 were seaplanes of four designs ; two
 
 The Beginning 19 
 
 were bombers of the pusher type and there were 
 31 pursuit 'planes of seven different designs. 
 
 The many different types, the few contractors, 
 and the limited number of contracts reveal pain- 
 fully that we had no program, no funds, and but a 
 limited comprehension of what was necessary. Of 
 the contractors only one the Curtiss Company 
 was large, as an all around airplane manufacturing 
 company and the rest were either motor makers 
 only, adjuncts, or feeble in resources or personnel 
 and generally lacking in the organization and under- 
 standing of quantity production. Their value con- 
 sisted more in their engineers than in their realized 
 production ability. The list of these contractors 
 is deserving of publication and record, for most of 
 them subsequently played a great part in the engi- 
 neering or production sides of the stupendous 
 building program that was finally embarked upon. 
 They were the Curtiss, the Standard, the Burgess, 
 the L. W. F., Thomas-Morse, Wright-Martin, 
 Sturtevant, Aero-Marine, Gallaudet, General Ve- 
 hicle, Pacific, Christofferson, Heinrich, New York 
 Aero, Pigeon Frazer, James V. Martin. Compe- 
 tent authority states that the first six in the list 
 were the only ones that had ever built more than 
 ten machines. That, perhaps, is a sufficient answer 
 to the question so often asked : Why did automo-
 
 20 Wings of War 
 
 bile and other manufacturers who were not pre- 
 viously in the business of making aircraft have so 
 much to do with the production program? 
 
 The domestic manufacturers or would-be manu- 
 facturers were profuse in their advice and sugges- 
 tions, each believing in his particular aeroplane or 
 engine or whatever else he had to offer and each 
 eager to win distinction and to contribute to the 
 success of the war. After and with them swarmed 
 the representatives of foreign manufacturers who 
 were anxious to dispose of their American rights 
 and sometimes to establish American plants. 
 Their offers ran into very high figures. The 
 royalties asked by some of them, reduced to 
 a basis of one thousand units for each, are as 
 follows : 
 
 Short seaplane $ 675,000.00 
 
 Sopwith 'plane 500,000.00 
 
 Clerget engine 700,000.00 
 
 Sunbeam (including cost of en- 
 gine and royalty) 200 H. P. . 7,000,000.00 
 300 H. P.. 8,000,000.00 
 
 Caproni rights 2,000,000.00 
 
 Gnome 1,215,000.00 
 
 Gnome, 100 H. P 500,000.00 
 
 Le Rhone, 80 H. P 1,375,000.00 
 
 Handley-Page 'plane 200,000.00 
 
 Le Rhone engine 600,000.00
 
 The Beginning 21 
 
 These offers and the support advanced for each 
 of them added to the bewilderment of the aircraft 
 officials and to the great body of criticism that 
 began to engulf them. Each representative whose 
 proposition was not promptly accepted or was 
 eventually rejected could demonstrate how the air- 
 craft organization was thereby failing to measure 
 up to its opportunities and responsibilities. This 
 was also true of some of the domestic manufac- 
 turers, though of the latter it must be said that in 
 the end, whether they considered that they had 
 been justly and understandingly dealt with or not, 
 they loyally undertook the task that was assigned 
 to them whether great or small. Nor can it be 
 asserted confidently that they all received their 
 deserts. Mistakes may have been made, doubt- 
 less were made. It could not be otherwise. Deci- 
 sions, right or wrong, had to be made or the early 
 confusion and indecision would have continued 
 indefinitely. The odds were all in favor of follow- 
 ing foreign practice, both in 'planes and engines 
 so far as combat airplanes were concerned.
 
 CHAPTER IV 
 
 MAKING UP FOR LOST TIME 
 
 THE declaration of war precipitated an in- 
 describable state of confusion in Washington. A 
 government whose energies had been largely 
 devoted to keeping out of war and defending the 
 rights of neutrals and whose inclinations were all 
 for peace found itself confronted by war modern 
 war, of which it was all but totally ignorant. In 
 striving for peace it had failed to prepare for war. 
 There is probably no parallel in history of a great 
 nation remaining for three years on the edge of a 
 war that involved its own future, reminded daily 
 of the huge scale of operations and their infinite 
 complexity, and yet doing almost nothing to arm 
 itself. The small aviation organization of the Signal 
 Corps was stunned. In the preceding months it 
 had gradually grasped the idea that if war came a 
 prodigious program would be inevitable, but the 
 preparations for realizing and preparing for it were 
 very meager. It called for help. In response the
 
 Making Up for Lost Time 23 
 
 Council of National Defense, which had for some 
 months concerned itself with the impending prob- 
 lem, created the Aircraft Production Board, which 
 thereafter became an independent body. 
 
 Like the body whence it sprang it had no real 
 powers. It sought to counsel, suggest, and advise; 
 and to coordinate and harmonize the aviation 
 efforts of the army and the navy. Howard E. 
 Coffin, an automobile manufacturer of great abil- 
 ity, industry, and self-sacrificing patriotism, who 
 had long been interested in preparedness and in 
 the development of aviation as an arm of the 
 national military power, was made chairman. The 
 other civilian members were Edward A. Deeds, 
 who was subsequently to assume, as chief of the 
 equipment section of the aviation division of the 
 Signal Corps, the task of directing program and 
 production; Sidney D. Waldon and Robert L. 
 Montgomery. The other members were Gen. 
 George O. Squier, Chief Signal Officer, and Adm. 
 D. W. Taylor, Chief of the Bureau of Construc- 
 tion and Repair of the Navy. 
 
 Congress was blindly called upon for huge appro- 
 priations and blindly made them. The Allies, 
 aware of the tremendous American capacity for 
 quantity production and knowing from their own 
 experience of the many obstacles in the way of
 
 24 Wings of War 
 
 such production, and being keenly convinced of the 
 importance of supremacy in aerial warfare, advised 
 that we undertake an aerial program that would 
 dwarf all that had been done by themselves or the 
 Germans. The popular imagination was capti- 
 vated by the concept of illimitable American manu- 
 facturing potentiality turned to the conquest of 
 the air. On May I2th, #10,800,000 was voted; on 
 June 1 5th, #31, 846,000, and finally on July 24th, 
 after the army air program had been decided upon, 
 #640,000,000. Later appropriations in this and 
 the following year made the grand total for the 
 air service, #1,676,000,000, which was cut to 
 #1,190,000,000 after hostilities ceased. 
 
 General Squier asked for the #640,000,000 more 
 on general principles than as the result of careful 
 calculation. He knew that the cost of the aviation 
 enterprise, if conducted on an adequate scale, would 
 be prodigious. But neither he nor anyone else 
 knew at that time what an adequate scale was. 
 Asked by one of his officers about this time con- 
 cerning the program, the General replied that there 
 was no program then and could not be one. 
 
 "Think of the largest program you can imagine 
 as possible," he said in effect, "and then double 
 it and probably you will not have it large 
 enough."
 
 Making Up for Lost Time 25 
 
 General Squier is a scientist and scholar rather 
 than an executive, but he is entitled to credit for 
 two policies that profoundly affected production of 
 aviation equipment and the size of preparations as 
 well as their manner of realization. He had been 
 abroad and had a wide understanding of the neces- 
 sity for extensive preparations. He, therefore, 
 opposed all half-way measures. He was for plung- 
 ing and plunging hard. He also gave his executive 
 heads unlimited authority, thus enabling them to 
 act with promptness and vigor. The Signal Corps 
 administration of aviation, therefore, lacked nei- 
 ther vision nor initiative. Whatever criticism may 
 be leveled at it, credit must be given to it for acting 
 energetically and comprehensively. 
 
 The will to great things was in existence and 
 the money was quickly provided, as it seems now, 
 though to an impatient country the time seemed 
 long then. But at first the aircraft authorities were 
 like a man on a desert island with a barrel of gold. 
 They did not know how to exchange their funds 
 for aircraft. 
 
 In January and February officers of the Signal 
 Corps had talked about the possibility of building 
 1000 'planes in 1917 or in twelve months, but in 
 the view of past experience with aircraft manu- 
 facturers, nobody believed it could be done. On
 
 26 Wings of War 
 
 March 23, Capt. V. E. Clarke prepared a report 
 that looked to the production of 2500 'planes a 
 year. By the middle of April a three-year program 
 was beginning to take form requiring the produc- 
 tion of 3700 'planes within the first twelve months 
 but it was never approved by higher authority 
 than General Squier. About the same time Mr. 
 Waldon, who as a manufacturer was anxious to 
 know what the program ought to be, got from 
 Colonel Bennett, who was then head of the aviation 
 section of the Signal Corps, an estimate based on 
 an army of one million which called for thirty-six 
 aero squadrons and 1296 military machines. Ten 
 training schools, it was calculated, would require 
 334 machines at the start and 500 during the 
 second six months to make good the wastage 
 or in all 834 training machines. On May I4th Mr. 
 Waldon made an estimate of 5158 machines for the 
 ensuing fiscal year. On May 23d the Joint Army 
 and Navy Technical Board raised this estimate to 
 7775 machines of which 7050 would be service 
 machines, and the rest for training. But on May 
 24th the French Government called on the United 
 States to undertake a program that would put 4500 
 machines at the front in the spring of 1918. The 
 Army and Navy Technical Board, acting on this 
 advice, then calculated that such an objective
 
 o 
 
 41 
 
 I 
 
 
 
 
 
 c 
 
 e 
 
 I 
 
 o
 
 Making Up for Lost Time 27 
 
 would call for about 22,500 airplanes of which 
 10,000 would be for training purposes and 12,000 
 for service. This, then, was the program to be 
 carried out in less than a year by an army that had 
 only 334 'planes on order and did not have more 
 than two dozen capable flyers on its rolls, and in a 
 country that had produced only 320 aircraft of all 
 kinds and on all orders, foreign and domestic, in 
 the first six months of 1917. 
 
 How amateurish the earlier estimates had been 
 is shown by the fact that whereas Colonel Bennett 
 had figured on more service than training 'planes, the 
 Technical Board at first calculated on ten times as 
 many training as service 'planes and finally decided 
 to make them about equal. The estimates for the 
 navy and for training foreign flyers brought the 
 total program up to 22,600 plus requirements for 
 replacements and wastage. At the most this was 
 a twelve-month program. 
 
 This program was, of course, physically impos- 
 sible, but in those days impossibility was not 
 admitted in connection with anything that the war 
 demanded. The men at the head of aviation 
 affairs believed it could be done, and the manu- 
 facturers believed likewise. 
 
 The civilian members of the Aircraft Production 
 Board, being men of large affairs and wide manu-
 
 28 Wings of War 
 
 factoring experience, were irked by their lack of 
 power and irritated by the inability of the army to 
 cope with such a great planning and production 
 problem. On the other hand the army men, who 
 were doing the best they could, retorted that it was 
 easy to advise but hard to do. The upshot was 
 that Mr. Deeds, yielding to the urging of General 
 Squier, accepted the chiefship of the equipment 
 division of the Signal Corps, which was created on 
 on Aug. 2, 1918, and was soon thereafter made a 
 Colonel in the regular army. The scope of the office 
 included both engineering and production for all 
 the requirements of the Signal Corps, aviation as 
 well as other. A finance and supply division, 
 already in existence, was reorganized and Mr. 
 Montgomery, subsequently commissioned as a 
 Colonel, was placed at its head. Mr. Waldon, 
 also commissioned as a Colonel, was chosen by 
 Colonel Deeds as his assistant chief. The two 
 divisions were united a little later with Colonel 
 Deeds at the head. 
 
 Congress later replaced the Aircraft Production 
 Board, created by the Council of National Defense, 
 with the Aircraft Board, and on October 22d 
 General Squier and Colonels Deeds and Mont- 
 gomery became the army members thereof (Colo- 
 nel Waldon having gone to France) ; and Admiral
 
 Making Up for Lost Time 29 
 
 Taylor, Captain Irwin.and Lieutenant Commander 
 Atkins the naval members. Richard Howe and L. 
 R. Thayer were added as civilian members, and 
 Howard E. Coffin continued as chairman. 
 
 Thus were established the bases of the organi- 
 zation of aircraft production, civilians in army 
 uniform taking up the stupendous task. In 
 January, 1918, Colonel Deeds was transferred to 
 General Squier's office with the still larger duties 
 of Industrial Executive. 
 
 Colonel Deeds as chief of the Equipment Divi- 
 sion and later as industrial executive was the 
 responsible head of army aircraft production. He 
 had been called to Washington by Mr. Coffin a 
 month before war was declared and appointed 
 by Secretary of War Baker to the short-lived 
 Munitions Standard Board. Two days before the 
 declaration of war Mr. Coffin again called on Mr. 
 Deeds for assistance in aviation matters and on 
 May loth invited him to become a member of the 
 Aircraft Production Board. This selection was a 
 judicious one as Mr. Deeds was a man of national 
 reputation as a successful manufacturer and engi- 
 neer, and had, as the friend and fellow-townsman 
 at Dayton of the Wright brothers, been long inter- 
 ested in aviation and had been associated with 
 Orville Wright in aeronautical experimentation.
 
 30 Wings of War 
 
 He was widely known as an excellent executive 
 and an acknowledged master of quantity pro- 
 duction and quantity production was what the 
 United States was expected to realize in the man- 
 ufacture of aircraft. Another special qualifica- 
 tion that peculiarly fitted Colonel Deeds for this 
 work was that he had had a very exceptional 
 experience in the developing of new highly tech- 
 nical apparatus and thereafter putting it success- 
 fully into quantity production, and it was well 
 understood that the work of producing aircraft in 
 this country would especially demand such quali- 
 fications. Europe had not succeeded in realizing 
 mass production by machine methods but it 
 was hoped that America, the acknowledged home 
 of such methods and of standardization and ma- 
 chine tools, would be able to do what the old 
 world had failed to do. Indeed, it was well under- 
 stood among American industrialists and mechan- 
 ical engineers that if we succeeded at all in attain- 
 ing volume in aircraft production it would have to 
 be by our characteristic methods of manufacture. 
 Colonel Deeds, as chief of the Equipment 
 Division of the Signal Corps, summoned to his 
 assistance the following men of affairs, believing 
 that as his job was in its simple outlines a big 
 manufacturing job, men who had done big things
 
 Making Up for Lost Time 3 1 
 
 in the business world were the ones to fill the 
 positions. 
 
 Sidney D. Waldon, later Colonel, active in the 
 Signal Corps aviation section since November, 
 1916, formerly vice-president and general manager 
 of the Packard Motor Car Company, afterward 
 associated with the Cadillac Motor Car Company, 
 and later acting in an independent consulting 
 
 capacity as an automobile engineer and executive, 
 
 % 
 
 was made assistant chief. 
 
 R. L. Montgomery, later Colonel, a banker of 
 experience in Philadelphia and New York, was 
 made chief of finance. 
 
 Melville W. Thompson, later Lieutenant Col- 
 onel, an expert accountant and valuator, of New 
 York City, was appointed assistant chief of finance. 
 
 George W. Mixter, later Lieutenant Colonel, 
 vice-president and manager of manufacture of 
 Deere & Company, a manufacturer of broad expe- 
 rience, who was placed in charge of all inspection. 
 
 J. G. Vincent, later Lieutenant Colonel, vice- 
 president Packard Motor Car Company, chief of 
 engine design. 
 
 Harry L. Shepler, later Major, production man- 
 ager of the Willys-Overland Company, chief of 
 'plane production. 
 
 Leonard S. Horner, later Lieutenant Colonel,
 
 32 Wings of War 
 
 general manager of the Acme Wire Company, of 
 New Haven, chief of production of instruments 
 and ordnance. Later he became the efficient ex- 
 ecutive officer of the Bureau of Aircraft Production. 
 
 W. H. H. Hutton, Jr., later Colonel, formerly 
 associated with the Timken Company. 
 
 Lieutenant Harold H. Emmons, U. S. N. R. F., 
 in civil life an attorney and manufacturer of 
 Detroit, as chief of engine production, "loaned" 
 to the army by the navy. 
 
 Each of these heads of sections chose his own 
 sub-executive from among the business men and 
 manufacturers of his acquaintance and confidence, 
 thus creating, as well as could be done in so short 
 a time, the counterpart of the executive organiza- 
 tion of a great manufacturing business in which the 
 members are bound together in an efficient whole 
 by mutual esteem, personal acquaintance, confi- 
 dence, and even personal friendship.
 
 CHAPTER V 
 
 SEEKING GUIDANCE 
 
 IP the men who were groping in the dark to find 
 some solid foundations on which to plan and build 
 in the early days of the war were frank to confess 
 their lack of knowledge of aeronautics and air- 
 craft, the country at large was full of well-meaning 
 men who knew precisely what should be done and 
 how it should be done. Inventors, dreamers, 
 aeronautical enthusiasts, business men without 
 expert knowledge, promoters without capital, man- 
 ufacturers without factories, and plain patriots who 
 wanted to help, descended in droves on the impo- 
 tent Aircraft Production Board and upon the 
 Signal Corps. The height of manufacturing ab- 
 surdity was reached by a thrifty patriot who 
 offered to dispose of a perfectly good clam-shell 
 dredging outfit as the nucleus of a plant to make 
 Nieuport pursuit 'planes. These self-constituted 
 advisors consumed hours and days of time of many 
 officials and afterward elected themselves all 
 
 3 33
 
 34 Wings of War 
 
 around critics and censors of all aircraft matters. 
 The whole air organization was like a town meet- 
 ing dealing with an abstruse problem in municipal 
 finances. Everybody was keen and eager and will- 
 ing to work but nobody precisely knew what to do. 
 There were many ideas, many suggestions, much 
 advice and few plans. It could not be otherwise. 
 Upon a small body of men inexperienced in this 
 particular field was thrown the overwhelming re- 
 sponsibility of doing in an impossibly short time 
 far more than had been done by the best technic- 
 ians and the most experienced makers of aircraft 
 in other countries in a number of years. Yet 
 there must be action and so the men in charge 
 began striking out in the dark to find something 
 solid and definite. The first thing they did was 
 to try to outline the task after the Army and 
 Navy Technical Board had finally decided on 
 a program calling for the production of 22,500 
 machines, and their quota of spare parts, 
 training and service. This is what confronted 
 them: 
 
 First : The manufacture of that many machines 
 without any definite knowledge as to what the 
 different types should be and without any real 
 information as to what was needed. 
 
 Second : The establishment of a comprehensive
 
 Seeking Guidance 35 
 
 system of training, training schools, technical in- 
 struction and training fields. 
 
 Third: The expansion of a peace-time organi- 
 zation of less than 1500 persons into a war-time 
 organization of more than 150,000. 
 
 Fourth : The enlargement of the aircraft manu- 
 facturing capacity of the country about three hun- 
 dred times. 
 
 Fifth: The creation of a large engineering and 
 technical force with but a ridiculously inadequate 
 nucleus with which to start. 
 
 Sixth : The ascertaining of the materials needed, 
 arrangements for their production, and the crea- 
 tion of many new industries to supply the equip- 
 ment of the 'planes all the way from dope for 
 the wing-coverings to machine guns. 
 
 The outlining of the problem only served to 
 remind how helpless the country was with respect 
 to the knowledge and experience needed to per- 
 form each part of it. 
 
 Naturally, the first thought was to appeal to the 
 Allies for advice and counsel. So, immediately 
 after the declaration of war, General Squier, 
 through the embassies, cabled to Europe asking 
 that aeronautical experts and aviation instructors 
 be sent to America. Next American mechanics 
 were sent abroad to learn foreign practice in manu-
 
 36 Wings of War 
 
 facture. Canada, as the nearest Ally, was ap- 
 pealed to for advice and example and responded 
 promptly. Then it was decided to send a com- 
 mission abroad to learn from the Allies what we 
 might and should do, for not only were we in mil- 
 itary aviation as little children compared to them, 
 but they held from the first the idea that the 
 American aviation effort should not be a perfect 
 whole but should be considered as a part of the 
 Allied aeronautical unit. 
 
 It is important to an understanding of what the 
 United States later did or did not, to grasp firmly 
 the fact that we were looked upon and so consid- 
 ered ourselves from the start, as the complement 
 of the Allies. This was the central idea and 
 whether it was sound or erroneous is now imma- 
 terial. The point is that our aircraft managers 
 must be judged by what they did in accordance with 
 a general scheme that they could not conceivably 
 have rejected even if it did not seem to them, 
 as well as to our Allies, to be the perfectly evident 
 course. In general the Allies were to tell us what 
 to do in order to fill out the common program 
 looking to control of the air. Thus it was that 
 the French determined the scale of our effort, and 
 the French and British together its general nature, 
 and French, British, and Italians acted as our
 
 Seeking Guidance 37 
 
 instructors. It is true, that as our aircraft mana- 
 gers began to get their bearings, they departed 
 somewhat from their instructions in their manner 
 of realizing the purpose, but throughout they 
 steadfastly sought to supply through the American 
 aviation effort what our more experienced friends 
 across the water judged we should. In detail this 
 counsel from abroad was often conflicting and con- 
 sequently confusing. While many and competent 
 experts soon came across the ocean, it became 
 evident that to get a clearer understanding of 
 what was required of us and also a more complete 
 knowledge of the state of aeronautical develop- 
 ment in Europe, as well as a more authoritative 
 understanding of the situation, it would be ne- 
 cessary for us to send representatives abroad to get 
 in touch with foreign sources of policy and prac- 
 tice and also with our own military commanders. 
 The Boiling Commission, as it was known, was 
 accordingly sent abroad about the middle of June, 
 1917. It was headed by Col. R. C. Boiling, who 
 was later to lose his life heroically in a revolver 
 battle with German officers after having unwit- 
 tingly entered the German lines, during the great 
 German offensive of March and April, 1918. The 
 army members were Captain Clarke (later Colo- 
 nel), and his assistant, Edgar S. Gorrell, after-
 
 38 Wings of War 
 
 ward Colonel, both being aeronautical engineers 
 of the then existing regular aviation organization; 
 Commander Westervelt and Lieutenant Childs of 
 the navy; and two civilian members, viz., Howard 
 Marmon, engineer of the Nordyke-Marmon Com- 
 pany of Indianapolis and an acknowledged expert 
 in the design and production of motors, and 
 Herbert Hughes, an accomplished engineer of the 
 Packard Company. 
 
 In the meantime the work of locating aviation 
 fields, expanding the service personnel and creating 
 the training organization were proceeding rapidly, 
 for these were tasks that were quickly compre- 
 hended in their outlines, rendered difficult though 
 they were by lack of trained aviators, instructors, 
 mechanics, and officers. The development and 
 expansion of these branches of the great work con- 
 stitute a vast subject in themselves and will herein 
 be considered in only a cursory manner, the proper 
 purpose of this book being an account and inter- 
 pretation of aircraft production in America during 
 the war.
 
 CHAPTER VI 
 TRAINING 'PLANES AND ENGINES 
 
 THE inevitable confusion and uncertainty that 
 existed in the early stages of the aircraft effort 
 were quite promptly dissipated in regard to train- 
 ing 'planes and engines. It was obvious that they 
 must be had before the combat equipment, and 
 in large numbers at an early date. As soon as the 
 size of the active air service was determined, the 
 approximate requirements for training became 
 easily calculable. Moreover, suitable 'planes and 
 engines for training purposes, at least in the earlier 
 stages, were already being made in this country. 
 The problem did involve some elements of choice 
 but mostly it was a problem of securing quantity 
 production of existing types. 
 
 The Curtiss Company had already achieved a 
 very considerable output of training airplanes, 
 making both the 'plane and the engine, for Canada, 
 and seaplanes for Britain; the Hall-Scott engine 
 was being produced in important volume; the 
 
 39
 
 40 Wings of War 
 
 Wright-Martin Company after long delay had 
 finally swung into production with the I5O-H. P. 
 Hispano-Suiza and the General Vehicle was put- 
 ting out about five lOO-H. P. Gnomes daily. Here 
 were definitely proved types already in production. 
 Also the Standard Aero Corporation had been 
 developing its Standard J 'plane for more than a 
 year, and was ready to proceed with production. 
 While the Curtiss 'plane and engine were gener- 
 ally considered superior to the Standard 'plane 
 equipped with the Hall-Scott engine, the latter 
 combination was recommended by the Joint Army 
 and Navy Technical Board as an alternative. It 
 appeared that no difficult engineering or produc- 
 tion problems were involved in these decisions, 
 though it did later develop that the drawings of 
 both machines, owing to the fact that they had 
 been entirely prepared for their own use by work- 
 men who were familiar with them, were not so 
 complete as required by manufacturers taking 
 them up de novo. Thus, although other plants 
 were brought into the production of these 'planes 
 and engines the outcome was not up to the require- 
 ments, the peak of production in engines being 
 reached in March instead of January, 1918. 
 
 The Willys-Morrow plant at Elmira, N. Y., 
 was called on for 5000 of the 0X5 engines, the
 
 Training 'Planes and Engines 4 1 
 
 Hall-Scott Company for 1250 of its Ay A engines, 
 and the Nordyke-Marmon Company for 1000 of tht 
 same, and orders for the corresponding number of 
 'planes and spares were placed with various manu- 
 facturers as follows : Curtiss Aeroplane and Motor 
 Corporation, Buffalo, N. Y., Engle Aircraft Com- 
 pany, Niles ; Fowler Aircraft Company, San Fran- 
 cisco; Springfield Aircraft Company, Springfield, 
 Mass., and St. Louis Car Company, St. Louis, 
 Curtiss JN 'planes ; Rubay & Company, Cleveland ; 
 Sturtevant Company, Boston ; Remington Aircraft 
 Company, Los Angeles, JN spares ; Standard Aero- 
 craft Company, Plainfield, N. J. (afterwards the 
 Standard Aircraft Corporation of Elizabeth, N. J.) ; 
 Dayton-Wright Company, Dayton, Ohio; Fisher 
 Body Corporation, Detroit; Glenn-Martin Com- 
 pany, Los Angeles, Standard SJI 'planes. 
 
 Had it not been for the difficulty presented by 
 the lack of complete working drawings, other large 
 manufacturing companies that had not hitherto 
 made aircraft might have been asked to assist, but 
 in the circumstances it was considered wise to give 
 contracts to a limited number of companies that 
 had some knowledge, experience, or understanding 
 of the work in hand. The contracts for spare parts 
 were given to companies which it was hoped would 
 later develop plants capable of making entire ma-
 
 4 2 Wings of War 
 
 chines. This indeed was the general policy of bring- 
 ing American manufacturers of other experience 
 into the aircraft work; that is, they were to be 
 started on parts and later and gradually prepare 
 themselves for complete production of training 
 'planes. Those who did well on training 'planes 
 would be graduated to the manufacture of service 
 'planes. This policy proved very successful , as later 
 developments showed. 
 
 The difficulty caused by lack of complete draw- 
 ings in the case of the Curtiss and Standard 'planes 
 serves to call attention to the fact that American 
 manufacturers, being accustomed to absolutely 
 standardized production, are unable speedily to 
 adapt themselves and their methods to the man- 
 ufacture of any new article unless they are pro- 
 vided with drawings that are complete in the 
 minutest detail. The European manufacturer, not 
 being so completely wedded to standardization and 
 machine production, can begin his comparatively 
 slower production sooner after taking up a new 
 thing. This elemental difference between Amer- 
 ican and European practice was the occasion of a 
 world of delay in the quantity reproduction of 
 European designs of engines and 'planes in this 
 country, and constituted one of the arguments for 
 the adoption of the Liberty motor instead of some
 
 <? 
 
 O
 
 Training 'Planes and Engines 43 
 
 approved European type. It is hard for the non- 
 technical mind to understand this, but its compre- 
 hension is of great importance because of its bear- 
 ing on the whole question of the transplantation 
 of the aircraft industry from Europe to America. 
 Where absolute standardization does not exist, 
 drawings that are complete in every detail are not 
 required, as the intelligent mechanic fills the gaps, 
 himself, with the parts of necessary size as he meets 
 them. But where the parts are all machine made 
 and standardized, the drawings must be complete 
 in every respect else the machine tools that make 
 the parts cannot be prepared, and machine tools, 
 wonderful as they are, are not capable of mak- 
 ing a different sized part of the same general 
 nature to fit the particular opening that may 
 have been left for it. The delays and difficul- 
 ties of this kind that are thus brought to mind 
 by the case of one American company that 
 had developed quantity production in its own 
 shops without absolutely complete drawings will 
 be mentioned and further dwelt upon in another 
 chapter. 
 
 While there has been much criticism of the 
 Standard training 'plane equipped with the Hall- 
 Scott engine and it was at a later period abandoned 
 by the Air Service when it had readied such a
 
 44 Wings of War 
 
 stage of sufficiency of equipment that it could be 
 hypercritical of what was delivered to it by the 
 production department, the record of casualties 
 in American training fields does not indicate that 
 its choice as an emergency measure was not wise. 
 Neither the 'plane nor the engine was considered 
 perfect, but it was known that they would meet 
 the purpose and they did. 
 
 The advanced training program called for the 
 use of a rotary engine which would train the stu- 
 dent for work in the small, swift pursuit 'planes 
 and for a fixed-cylinder type of engine that would 
 familiarize him with the use of machines of greater 
 speed and power. The IOO-H. P. Gnome rotary 
 was being made in small quantities by the General 
 Vehicle Company, but neither the Gnome I5O-H. P. 
 rotary nor the Le Rhone 80 H. P. was available, 
 yet the recommendations from Europe were for 
 the production of 5000 of the I5O-H. P. Gnome 
 and 2500 of the 8o-H. P. Le Rhone. As so many 
 Gnomes were entirely beyond the capacity of the 
 General Vehicle Company an effort was made to 
 get the General Motors Company to cooperate 
 with the General Vehicle Company and take the 
 burden of production with its many and large 
 plants, having the advantage of the General 
 Vehicle experience. Before this arrangement was
 
 Training 'Planes and Engines 45 
 
 consummated the word came from France to 
 abandon the I5O-H. P. Gnome. 
 
 Meanwhile, the Union Switch and Signal Com- 
 pany, of Swissvale, Pa., a Westinghouse subsidi- 
 ary, was persuaded to take up the task of making 
 2500 of the 8o-H. P. Le Rhone. " Persuaded " is 
 the word, for this company, like most of the other 
 great American manufacturing companies, recog- 
 nized fully the numerous and baffling difficulties 
 that were certain to be encountered in producing a 
 machine of European design by American manu- 
 facturing methods. The company's reluctance was 
 well justified by the event, for even though a com- 
 plete engine was received from France in Sep- 
 tember, the drawings that accompanied it did not 
 agree with it in all respects, either in design or 
 dimensions, nor was it accompanied by complete or 
 accurate drawings, and precise specifications and 
 metallurgical instructions. These may seem triv- 
 ial matters, but it took months to revise and check 
 the drawings and then still more time to prepare 
 the detail drawings necessary for standardized pro- 
 duction. Owing to the inaccuracy of the metallur- 
 gical instructions every part of the engine had to 
 be chemically analyzed, in order to ascertain its 
 composition. Finally it was necessary to bring 
 from France M. Georges Guillot, the engineer of
 
 46 Wings of War 
 
 the Gnome-Le Rhone factories. So it was not 
 until May, 1918, that the -Union Switch and Signal 
 Company, one of the most competent manufac- 
 turing corporations in America, with all of its own 
 great engineering ability and the assistance ex- 
 tended to it by M. Guillot and the engineers of 
 the Signal Corps, was able to begin production. 
 Associated with this Le Rhone achievement were 
 Lieut. Frank M. Hawley, government engineer 
 in charge, and Alex. K. Hamilton, Pittsburgh, 
 district manager of engine production, and his 
 assistant, Frank C. Moore. It should be remem- 
 bered that this Le Rhone engine is a small affair 
 of only 80 H. P. That so much difficulty was 
 encountered in getting it into quantity production 
 of a comparatively small total number is a hint 
 of the vastly greater and more widespread involve- 
 ments of time and manufacturing plants that would 
 have followed the reproduction in America of a high- 
 powered foreign engine by the tens of thousands. 
 
 This is an appropriate place again to direct 
 attention to the fact that to take up an European 
 design even of the most accepted and proved type 
 and undertake its quantity production in America 
 is by no means the simple thing it seems when sug- 
 gested. It is far more than a parrot-like imitation. 
 Because America does not produce by hand and
 
 Training 'Planes and Engines 47 
 
 has not the kind of mechanics that thus build 
 machines, any European machine that is brought 
 here for manufacture must go through a consid- 
 erable period of adaptation to American methods, 
 whether these be merely multitudinous and tedious 
 drawings of the parts and the tools, jigs, and fix- 
 tures to make them, and the making of the tools, 
 or of actual changes in the detail of design to fit 
 American shop practice. The fact is that ordin- 
 arily a new American design, can be put into 
 quantity production in American shops sooner than 
 an imported design, even though it be accom- 
 panied by a completed machine. The machine and 
 the human do not manufacture in the same way. 
 Had we but begun to naturalize the standard 
 European types of engines and 'planes in this 
 country a year before the war, even if we had not 
 essayed quantity production, there would have 
 been all the difference in the world, not only in the 
 prompt and voluminous production of primary and 
 secondary training engines, but even in the foreign 
 combat engines and 'planes. That this was not 
 done is not the fault but rather the grave misfor- 
 tune of the men who were called upon to do every- 
 thing years too late. 
 
 The story is the same with the Hispano-Suiza 
 engine which was chosen as the power plant of the
 
 48 Wings of War 
 
 advanced training machines, with the Curtiss JN 
 'plane. The Wright-Martin Aircraft Corporation 
 had acquired the American rights for this motor in 
 the latter part of 1915 and had begun work on 
 its Americanization in January, 1916. Yet it was 
 February, 1917, thirteen months later, after in- 
 finite efforts and the expenditure of millions of 
 dollars, that the first machine-tool production 
 machine came through. The Wright-Martin Com- 
 pany was originally working on a contract from 
 the French Government, but at an early date a 
 large American order was placed with it for 150- 
 H. P. Hispano-Suizas for advanced training and 
 even, as was thought at first, for combat purposes, 
 but the 150 H. P. soon fell behind the procession 
 of military aeronautical advance for that purpose. 
 
 Including 451 Lawrence engines, the manufac- 
 turers of engines for training purposes had deliv- 
 ered 16,134 up to the signing of the armistice 
 (this number was considerably increased before 
 production ceased), of which about 500 went to 
 the navy directly, about 300 to the A. E. F., and 
 the rest were incorporated into training 'planes at 
 home, the distribution by types being OX, 8458; 
 Hispano-Suiza, 3549; AyA, 2250; Gnome, 280; Le 
 Rhone, 1298; Lawrence, 451. 
 
 These experiences with the Americanization of
 
 Training 'Planes and Engines 49 
 
 foreign engines showed that by the time European 
 types could be brought to mass production here 
 they were far behind European development. It 
 requires in Europe at least one year to design and 
 develop a new engine to the point of determining 
 its value. Another year is required to attain mass 
 production in this country. So the original design 
 is two years old when production begins here. 
 Thus the loo-H. P. Gnome and the I5O-H. P. His- 
 pano were both obsolete for service use by the time 
 our manufacturers could make deliveries. 
 
 In getting a proper perspective on the aircraft 
 production effort care must be taken to give due 
 consideration to the production of training engines 
 and 'planes. The public attention was naturally 
 concentrated on combat 'planes and the engines 
 that went with them, notably the Liberty motor. 
 The public was paying for results and was dis- 
 posed to overlook the laborious toil, the many 
 manufacturing difficulties and the time required 
 for preparation for air power. The fact that while 
 combat engines and 'planes were being designed 
 and produced, a great manufacturing feat was per- 
 formed with respect to the training apparatus and 
 equipment is and was entirely overlooked. The 
 Liberty motor, the De Haviland 4, the great 
 bombers, the big seaplanes all these were spec-
 
 50 Wings of War 
 
 tacular and appealed to the public imagination, 
 just as soldiers at the front in Prance interested 
 the public more than soldiers tediously drilling in 
 camps at home. The humble training 'planes and 
 motors without which the fighting airplanes would 
 never be utilizable were almost forgotten. While 
 the public was "fed up" with accounts of delays 
 and disappointments in the production of the 
 fighting aircraft it was not informed that the man- 
 ufacturers and the aviation division of the Signal 
 Corps were making a marvelous record in the pro- 
 duction of training apparatus. The production 
 began with 9 'planes in June, 1917, and gradu- 
 ally increased until the maximum was reached in 
 January, 1918, with an output of 729. There- 
 after, training requirements being well in hand, 
 the output slowly decreased until it fell to 162 a 
 month just after the armistice was signed. Rough- 
 ly, then, it may be said that within the first year 
 of the war, notwithstanding the confusion that 
 inevitably existed at first and that led to some loss 
 of time, the aircraft managers found ways to pro- 
 vide the training 'planes and engines, not to men- 
 tion the thousand and one other accessories of 
 training, for an aviation organization of more than 
 one hundred and ninety thousand men of whom 
 about one- tenth were student aviators.
 
 CHAPTER VII 
 
 THE BOLLING COMMISSION AND FOREIGN 
 ASSISTANCE 
 
 THE Boiling Commission, whose composition 
 has been given elsewhere, was sent abroad to 
 secure information as to what the Allies expected 
 of us, how we should proceed to carry out that 
 advice, to confer with General Pershing and his 
 staff in regard to their aviation requirements, and 
 generally determine the objectives of the American 
 aviation effort. 
 
 The members of this commission soon came to 
 a clear understanding of the absolute impossi- 
 bility of any extensive American contribution to 
 the numbers of service machines at the front before 
 the summer of 1918. When this situation was 
 explained by them to General Pershing, it was 
 decided to procure as many machines from foreign 
 manufacturers as possible both for service and for 
 advanced training of our aviators in France, it 
 having been decided that advanced training un- 
 
 51
 
 52 Wings of War 
 
 der the circumstances could best be provided in 
 France. 
 
 The French manufacturers were very confident 
 that besides supplying all of the needs of their own 
 army they could within a year provide the Amer- 
 ican air service with sixty-five hundred 'planes and 
 about eighty-five hundred service engines, besides 
 about a thousand training 'planes with their 
 engines, provided that they could be supplied with 
 materials from the United States. This was most 
 encouraging information, for it seemed to promise 
 fighting machines on a par with those used by the 
 Allies much sooner than anything like such a num- 
 ber could be produced in the United States, where 
 the service machine industry was non-existent. 
 Such a course pointed to the quickest possible 
 route to American aviation representation at the 
 front, in large measure relieved American manu- 
 facturers from the necessity of making the pursuit 
 machines, and left them free to concentrate on 
 the high-powered engines and larger types of 
 'planes, for reconnoissance, night and day bomb- 
 ing, etc., which was what the Allies seemed to 
 expect of us. Moreover, as the fashions in pursuit 
 'planes changed almost daily, it was felt that it 
 was an ideal arrangement to have them made 
 almost in sight of the battle line and in immediate
 
 The Boiling Commission 53 
 
 communication with its changing requirements. 
 The European system of manufacture was, too, 
 especially adapted to meeting changes during the 
 course of construction. 
 
 Nor did it appear at the time that this was 
 imposing an unwelcome and onerous burden on 
 the French. It appeared, on the contrary, that 
 the capacity of their factories had advanced be- 
 yond their own requirements and that it was a 
 piece of fine inter- Allied economy to use their faci- 
 lities for the common end. Here, however, as at 
 home there was to be a disappointment in per- 
 formance. The more experienced French manu- 
 facturers were as overoptimistic as to their ability 
 as our inexperienced manufacturers and managers 
 were. According to the schedule all the machines 
 were to be completed by June, 1918, and the rate 
 of production was to go as high as eight hun- 
 dred in January; eleven hundred in February; 
 fourteen hundred in March, and thence decline. 
 About 6000 airplanes were ordered from French 
 manufacturers, as follows: Nieuport training, 
 725; Spad training, 150; Spad service, 2000; 
 Breguet service, 1500; New Spad or Nieuport 
 service, 1500. Instead of the 6000 only 1299 
 airplanes were actually delivered up to May 23, 
 1918, of which 1 1 80 were the various Nieuport
 
 54 Wings of War 
 
 types; in addition 532 machines of various types 
 were obtained from French sources, so that the 
 A. E. F. at the end of a year had only 1832 ser- 
 vice and training 'planes, instead of the 6000 
 promised. By the time the armistice was signed 
 the total number of foreign made machines, 
 including some English and Italian, had grown 
 to 5071. 
 
 The failure of the French manufacturers was 
 due partly to an impossible schedule, partly to our 
 failure to deliver all of the material promptly, but 
 especially to the increased demands of the French 
 aviation service, which even led to the diversion 
 of much of the American machinery and material 
 in the manufacture of machines for the French 
 army. On the whole, though, the contract to 
 deliver materials was very well carried out and 
 constitutes a performance that is greatly to the 
 credit of the aviation executives, considering that 
 it was undertaken simultaneously with the throes 
 of the great production effort in America. Some 
 ten million dollars' worth of an almost unlimited 
 number of articles or commodities were collected 
 and shipped through the agency of J. G. White 
 & Company, of New York. The shipments 
 included five million feet of lumber, one thousand 
 tons of machine tools, fifteen thousand tons of
 
 
 French-Made American Spad at the Front 
 
 "The Flying Fish," a Decorated Nieuport at the Front 
 
 U. S. Air Service Photo
 
 The Boiling Commission 55 
 
 materials and supplies such as steel, brass, copper, 
 and aluminum tubing; steel, copper, lead, and 
 aluminum sheets; bar steel, tool steel, structural 
 steel, ball-bearings, crank shafts, turn-buckles, 
 radiator tubes, wire cable, bolts, screws, nails, 
 fiber, cloth, felt, and rubber. Moreover, 19,000 
 mechanics were sent to France and England and 
 fabricated parts for 9000 engines and 1800 'planes, 
 besides 150,000,000 feet of airplane lumber, and 
 more than 30,000 tons of wood chemicals. r 
 
 1 The following summary of aviation aid furnished by the 
 United States to the Allies was laid before the House of Repre- 
 sentatives Committee on Naval Affairs (aviation hearings, second 
 session, Sixty-sixth Congress, p. 1525): 
 
 "Aid Furnished Allies by America. Under an agreement with 
 France, made in the fall of 1917, France was to furnish certain 
 airplanes and engines to the American army. America was to 
 furnish certain material and fabricated parts to France. How- 
 ever, it was distinctly agreed that France's delivery of planes 
 and engines was not dependent upon American delivery of raw 
 materials. This agreement meant the delivery of 23,000 tons of 
 material, and of this amount 46 per cent, had been delivered by 
 December 31, 1917, 84 per cent, by March 31, 1918, and 96 per 
 cent, by June 30, 1918. Included in these deliveries were fabri- 
 cated parts sufficient for 9000 engines and 1800 planes. In 
 addition to this the American army delivered to the Allies 150,- 
 000,000 feet of airplane lumber and over 30,000 tons of wood 
 chemicals. Prior to the armistice we furnished 1422 Liberty 
 engines to our Allies. We furnished to the British 15,000 me- 
 chanics and over 4000 to France. In fact, the Allied air pro- 
 grams of the various countries depended absolutely upon the help 
 of America. The aid of the American army enabled the Allies to 
 produce the materials they furnished us and placed them in far 
 better position to supply both their needs and ours than they would 
 have been to supply their own needs alone without our help. ' '
 
 56 Wings of War 
 
 It was not until December, 1917, that the French 
 indicated that they would have to default on their 
 contract. Though America had not provided all 
 the materials on schedule time, the chief reason 
 was that when M. Loucheur became the French 
 Minister of Munitions he decided to double the 
 French aviation production program and notified 
 the A. E. F. that it could not rely upon the French 
 contractors carrying out their contracts. This 
 change in the French program, rather than lack 
 of materials, was the true reason of the non-reali- 
 zation of the general scheme of having the Allies 
 fully supply our service and overseas training 
 'planes until the middle of 1918. In fact, the con- 
 tracts provided that in the event of American 
 materials not arriving as per schedule the French 
 would draw on their own supplies and replace them 
 later from the American stocks. The practical 
 canceling of the French contracts was serious 
 from the American point of view, but from the 
 standpoint of Allied aircraft success considered as 
 a unified whole, which was the governing principle 
 of American cooperation, it was not such. The 
 American individual aerial effort during the war 
 was thereby circumscribed, but the French effort 
 was correspondingly extended and intensified. 
 
 It will be well here to emphasize the fact that
 
 The Boiling Commission 57 
 
 the underlying conception of the American par- 
 ticipation in the aerial branch of the war was that 
 it was to be a part of a unified whole. We were 
 called upon to do what we could best do to con- 
 tribute to the success of the common cause, and 
 the Allies were to do likewise. Thus the American 
 program was never a symmetrical whole and had 
 to be altered from time to time to suit the chang- 
 ing conditions of the common effort, and was even 
 more important as a common source of mechanics, 
 materials, and parts than as a contributor of a 
 separate military face. 
 
 One of the things required of the Boiling Com- 
 mission was that besides investigating European 
 types of engines and 'planes with a view to advis- 
 ing regarding their manufacture in this country 
 it should procure and send samples of different 
 engines and 'planes as soon as possible, so that our 
 engineers would have models from which to make 
 drawings and otherwise prepare for production. 
 This seemed a thing as simple and as easily to be 
 performed as it was necessary. But, whatever the 
 cause, these samples, even when procurable, were 
 very long in reaching America. This simple failure 
 serves to illustrate the difficulties in the way of 
 putting foreign machines into production in Amer- 
 ica. Six types of engines and six of 'planes, the
 
 5 Wings of War 
 
 number of samples of each varying from two to 
 eight, were asked for from France; three types of 
 'planes and engines from Italy, and ten from 
 England, ranging from two to sixteen in number 
 of samples. Also four of the Lorraine-Dietrich 
 engines were requested from France. 
 
 The first sample to arrive was a De Haviland 4, 
 which reached Washington, July 27, 1917, without 
 engine, ordnance, or any of the other accessories 
 which go to make up a fighting airplane. The last 
 of the samples did not arrive until the following 
 winter. The fact that we had been at war four 
 months before it was possible to get the first sam- 
 ple of a combat machine to America throws a great 
 light on the feeble beginnings with which the 
 designers and makers of aircraft had to start. 
 
 It seemed a simple thing to say, "Reproduce 
 approved foreign designs in America," and an 
 obvious thing to do. But it was maddening to 
 find that the samples were incomplete and draw- 
 ings insufficient. If at the start complete draw- 
 ings of European engines and 'planes that it was 
 desired to put into production in this country could 
 have been secured, the output of service 'planes, 
 at least, would have been realized on a large scale 
 several months before it was. An American manu- 
 facturer will undertake almost any feat of produc-
 
 The Boiling Commission 59 
 
 tion if he can have the necessary drawings and 
 blue prints complete at the start. They are the 
 soul of machine-method quantity production. 
 
 If someone had had the foresight to study 
 European models of fighting aircraft and prepare 
 from them merely one complete set of drawings in 
 the year preceding our entry into the war, we could 
 have produced chasse machines for service at the 
 front sooner than the aviators could have been 
 trained to use them. We would not have had to 
 rely on the French for an insufficient number of 
 them, and at the same time our development and 
 production of high-powered engines and large air- 
 planes could have gone on unimpeded. In the 
 same way the production of the larger 'planes 
 would have been greatly expedited. For while, 
 in the end, we came to rely chiefly on the Liberty 
 motor, which was not conceived until the latter 
 part of May, 1918, the lack of accurate drawings 
 and other data regarding the De Haviland as well 
 as the big night-bombing 'planes greatly delayed 
 their production. 
 
 A scrap of paper is a little thing. The war in 
 Europe began with the tearing up of one. A few 
 scraps with drawings on them filed in a few pigeon- 
 holes in Washington might have ended the war 
 six months sooner.
 
 60 Wings of War 
 
 Without going into detail as to the recommen- 
 dations of the Boiling Commission, it may be said 
 that its recommendations and those of General 
 Pershing tended toward the idea that the business 
 of the United States was to produce aerial engine 
 power in great volume and in large units, both 
 for itself and for the Allies, and corresponding 
 types of 'planes. It is important to grasp this fact 
 fully. It explains why even on the last day of the 
 war there was not a single-seater fighter of Ameri- 
 can make at the front. There were none there 
 because they were not on the American program. 
 
 As early as December 14, 1917, General Pershing 
 cabled: "United States should leave production 
 single-place fighter to Europe." Prior to that 
 elaborate preparations had been made to manu- 
 facture the Spad in this country, but on receipt of 
 this cablegram the order was canceled. Even 
 before this time the trend in Europe seemed to 
 be away from the single-seater and toward the 
 two-seater, and it was the opinion in both Paris 
 and London in January, 1918, that no more of the 
 former would be ordered after July by either France 
 or England. Europe felt amply able to supply 
 itself and us with whatever single-seaters might be 
 needed, and, owing to proximity to the front, with 
 a quicker appreciation of the lessons of experience,
 
 The Boiling Commission 61 
 
 better than we could possibly do it. So, we repeat, 
 we made no single-seater fighters because we pur- 
 posely left them off our program, on the advice 
 of foreign authorities and our own representatives 
 abroad. Our general plan, then, was : 
 
 First: Early attainment of quantity produc- 
 tion of two-place machines of the observation type, 
 such as the De Haviland 4 and its modifications. 
 
 Second: Follow with quantity production of 
 two-place machines of the fighting type, such as 
 the Bristol. 
 
 Third : Come on as rapidly as possible with the 
 great bombing machines such as the Handley-Page 
 and the Caproni. 
 
 Owing to its great speed, when equipped with 
 the Liberty motor and its powerful armament, 
 the De Haviland 4 was really a three-purpose 
 'plane, viz., observation, bombing, and defensive 
 fighting. 
 
 "The decision not to proceed with the single- 
 seater type of fighting machine (i. e. the Spad)," 
 says an official statement, recently issued, "was 
 undoubtedly based on the conclusion reached in 
 the fall of 1917 that the era of independent fight- 
 ing was almost gone. Flying and fighting in 
 formation offered marked advantages. There 
 are no blind spots in a formation of fighters,
 
 62 Wings of War 
 
 each equipped to fight to the front, to the 
 rear, and to the sides." If formation fight- 
 ing were the coming tactics of the air it 
 appeared that there was little use for the single- 
 seater. Its chief value is its superior maneuver- 
 ability but formations are essentially unwieldy. 
 They were to be protected by their armament 
 rather than by manipulation. As a matter of fact 
 further development of squadron flying brought 
 the single-seater into greater favor; in the mean- 
 time we had definitely eliminated it from our pro- 
 gram. But in so fickle a matter, it might have 
 turned out that we had made single-seaters only 
 to find them useless. As it was we didn't make 
 them only to find them desirable. But on this 
 point it should be said that considering the facili- 
 ties of Europe for providing single-seaters it was 
 better that we should have neglected them than 
 the various types of two-seaters. We followed the 
 best advice we could get and the best judgment of 
 General Pershing and the Boiling Commission, 
 though it transpired that just as we abandoned 
 the chasse machines the front began to appreciate 
 them more than ever.
 
 CHAPTER VIII 
 
 ORIGIN OF THE LIBERTY ENGINE 
 
 THE demand from all quarters of Allied air 
 effort was for an engine of high power. When we 
 entered the war Europe was rapidly growing away 
 from the smaller engines. Practically every 
 proved and accepted engine then in service was 
 acknowledged to be behind the times. European 
 inventors and manufacturers were working on 
 engines of much greater horse power than had 
 hitherto been used. So far as taking a proved 
 European engine and putting it into production 
 in this country was concerned, it was certain that 
 by the time production had been attained, it would 
 be more or less antiquated for those uses calling 
 for motors of large power. There was nothing to 
 do but to take the risk in part, for some kind of a 
 motor in large numbers was better than none. 
 That being the case, the obvious thing to do was 
 to stimulate the production of those European 
 types that had already been put into production 
 
 63
 
 64 Wings of War 
 
 in this country and to limit the new effort to such 
 a machine as the Le Rhone which was likely to be 
 of some utility either for advanced training or for 
 pursuit service 'planes. So, our aircraft executives 
 did promptly take up the Hispano-Suiza 150 H. P. 
 which the Wright-Martin Aircraft Corporation 
 formerly the Simplex Motor Company had finally 
 put into successful production and the ico-H. P. 
 Gnome which was in minor production by the 
 General Vehicle Company, and proceed from the 
 beginning with the Le Rhone. Even with this 
 conservative decision, it was soon found that the 
 little Gnome would have to be abandoned and 
 that the Hispano-Suiza would have to be remod- 
 eled to give greater power. 
 
 As to the problem of the demand for a motor 
 of far greater power than had yet been success- 
 fully developed, the first suggestion was that we 
 take up one or more of the new foreign engines 
 which were then being developed but were not in 
 production, such as the Bugatti and the Lorraine- 
 Dietrich. There was also the Rolls-Royce, which 
 was then the most highly powered engine in use 
 in Europe. It seemed that the proper course to 
 take was to join in the development of the untried 
 foreign engines and begin immediately the produc- 
 tion of the Rolls-Royce in this country. These
 
 Origin of the Liberty Engine 65 
 
 matters, however, had to be left in the early 
 months very largely to the determination of the 
 Boiling Commission. In other words it was impos- 
 sible to arrive promptly at a judicious decision, 
 and it was felt that we must not make the mistake 
 the Allies had made of littering their training fields 
 and the battle front with innumerable different 
 designs and types of 'planes and engines. The 
 French and English were experimenting with or 
 producing eighty-three different types of engines 
 and 'planes none of them fully standardized 
 with chaos in factories, machine shops, repairs, and 
 replacements. The Germans had concentrated on 
 a few types of engines and 'planes and their gen- 
 eral efficiency in the air was largely due to this 
 fact. This was one of the lessons of the war up to 
 that time. It would have been folly for us not to 
 have acted in accordance with it. 
 
 Within six weeks after we entered the war we 
 had decided on these three things with respect to 
 engines: 
 
 First: We would make use of the accepted 
 American engines, which were adapted to train- 
 ing purposes. 
 
 Second: We would put into production three 
 types of foreign engines, which promised possi- 
 bilities of early realization of quantity production
 
 66 Wings of War 
 
 engines that seemed likely to be of some service 
 in the program, regardless of the daily growing 
 demand for engines of greater power. 
 
 Third : We would proceed as promptly as pos- 
 sible with the selection of one or more types of 
 the then developing high-power foreign engines. 
 Because of the lack of information an early de- 
 cision was here impossible, except in the case of the 
 Rolls-Royce, and unexpected difficulties of another 
 nature arose in connection with it, difficulties 
 that will be explained in another chapter. 
 
 The impossibility of an early decision in this 
 vital matter led to one of the grand decisions of 
 the war a decision whose boldness was of the 
 kind that stakes all on a single resolve. Mr. E. A. 
 Deeds, afterwards Colonel, was in May, 1917, 
 simply a member of the impotent Aircraft Pro- 
 duction Board, but as such he was involved in all 
 the deliberations and determinations of the hour, 
 as well as all its bewilderments and futilities. As 
 a great manufacturer and a successful executive, 
 used to prompt decisions and swift performance, 
 as one thoroughly familiar with the great produc- 
 tive capacity and mechanical engineering ability 
 of America, and especially of the automobile indus- 
 try, it was maddening to him to think of the gulf 
 between potentiality and realization.
 
 Origin of the Liberty Engine 67 
 
 Must this resourceful and industrially powerful 
 America wait for months before it could choose the 
 great motor or motors of the war? Must the 
 great potential capacity of the nation for the pro- 
 duction of aerial power remain inert while the 
 coming engine was chosen from the European can- 
 didates for the honor? The tendency had been 
 all toward such a paralyzing delay. Americans 
 were infants in aircraft engineering and manu- 
 facturing, as such, and were properly humble and 
 desirous of following foreign precepts and instruc- 
 tion. But as he chafed at the delay it was borne 
 in on Colonel Deeds, who was coming more and 
 more to be looked upon as the evolved leader of 
 the inchoate aircraft organization, that after all 
 an aircraft motor was nothing more than a highly 
 refined and specialized internal combustion motor. 
 We had not undertaken to make the highest types 
 in this country because there had been in them 
 no business appeal to the great manufacturers of 
 motors. An aerial motor of extraordinary power 
 was a new thing, then on the lap of the gods. Our 
 motor engineers were familiar with all the princi- 
 ples of design and they knew the essential require- 
 ments of materials. Why, since a new thing was 
 demanded by the progress of aerial warfare, should 
 not America bring it forth? Months might thus
 
 68 Wings of War 
 
 be saved in choosing an engine and months more 
 in achieving quantity production of it. While ex- 
 ploring Europe for the coming engine why not ex- 
 plore America as well, and take the great chance 
 of beginning to do something great? 
 
 The momentous decision was reached about the 
 25th of May, 1917. At any rate it was on that 
 day, less than three weeks from his entrance into 
 the aircraft council, that Mr. Deeds communicated 
 to Mr. Waldon, with whom he was most intimately 
 associated, his decision to undertake to produce 
 a new, high-powered, unit-system, standardized 
 American motor, which according to the number of 
 cylinders would give, in the different steps of 
 power required for different purposes of aerial use, 
 the maximum of power combined with the mini- 
 mum of weight. 
 
 Mr. Waldon received the idea enthusiastically, 
 for he had been thinking along much the same 
 lines as Mr. Deeds. In his mind the idea was 
 reinforced by his experience in connection with 
 official aviation matters since the preceding 
 November. 
 
 Each passing month had reminded him that 
 while the adoption of European models in part or 
 altogether was inevitable, the gap between the 
 time of adoption and the time of attainment of
 
 Origin of the Liberty Engine 69 
 
 quantity production would be intolerably long and 
 tedious. He had been greatly impressed by the 
 fact that it had taken the Wright- Martin Com- 
 pany with a capable engineering organization, 
 with numerous models, the completest drawings 
 and specifications, according to European ideas, 
 and the assistance of a numerous staff of French 
 engineers and mechanics thoroughly familiar with 
 practical production in the home factories of the 
 Hispano-Suiza, thirteen months and the loss of 
 millions of dollars to get into production. He was 
 also familiar with the somewhat similar experience 
 of the General Vehicle Company in transplanting 
 the Gnome. 
 
 American manufacturing methods are basically 
 the methods of machine-tool production. Euro- 
 pean methods are basically the methods of the 
 expert and intelligent mechanic and machinist. 
 The European has not our perfection of machines ; 
 we have not his perfection of the mechanic at 
 least not in such numbers as to give quantity pro- 
 duction. You can introduce a mechanic or a group 
 of mechanics to a machine, provide the materials 
 and hand-tools, and tell them to make others like 
 it. In a few days, or a few weeks, they will be in 
 production on a small scale. You cannot intro- 
 duce a model of a machine to a machine-tool or a
 
 X> Wings of War 
 
 group of them and tell them to begin forthwith to 
 reproduce their fellow. In fact you must first 
 make the machine-tool. And then it is only me- 
 chanical not human. American manufacture is 
 the mechanical making of parts by the thousands 
 each precisely like its predecessor and then the 
 assembling of those parts into the machine each 
 exactly, too, like its predecessor. Nothing can be 
 left to chance or fitting or adaptation by the work- 
 men. The workmen are manipulators of machines 
 not mechanics in the European sense. Before 
 production in quantities in America, therefore, 
 must go a tedious period of preparation the mak- 
 ing of thousands of drawings of the parts, the in- 
 finitely careful preparation of the dies, then the 
 thousands of tools, jigs, fixtures, etc., and also the 
 machines that are to apply these tools in the mak- 
 ing of the parts. All this process has to be gone 
 through with an American design as well as an 
 adopted foreign design, but in the case of the 
 American design the engineering and the drawings 
 are from the start adapted to American manufac- 
 turing methods. In the case of the foreign machine 
 the drawings are not only inadequate for machine 
 reproduction but parts are not designed with a 
 view to much adaptation. It is impossible quan- 
 titatively to reproduce a complex foreign machine
 
 Origin of the Liberty Engine 7 1 
 
 in this country without changing the shape and 
 design of its parts to some extent. 
 
 So, both Messrs. Deeds and Waldon perceived 
 a distinct advantage in the creation of an Ameri- 
 can type. In the stage of design and experimen- 
 tation, moreover, while much might be gained, 
 nothing was to be lost except the trivial cost of 
 the development work; the survey of European 
 engines proceeding undeterred. The critical de- 
 cision would come when the moment arrived to 
 accept the proposed American motor and order it 
 into expensive and extensive production. 
 
 The decision arrived at by Colonel Deeds clari- 
 fied the American aviation problem to a very- 
 great extent. Its successful realization put us into 
 the aerial side of the war with American-made 
 equipment to the degree which the early termina- 
 tion of the war and the vicissitudes of the realiza- 
 tion of the decision permitted. 
 
 But for this decision and the vigorous ways in 
 which action followed in those rough-and-ready 
 days before the strait- jacket of military red-tape 
 had encompassed the resourceful and highly 
 initiative civilians who were left to face the 
 problem, there would not have been a single 
 American-made airplane in France when the war 
 ended.
 
 72 Wings of War 
 
 The number of such airplanes in France and in 
 service when the armistice was signed was much 
 larger than commonly realized. Out of the 3227 
 De Haviland 4's actually delivered by November 
 n, 1918 (since increased to 4842), according to the 
 official statistics, 1885 had been shipped abroad, 
 1185 had been received at the French ports, 1025 
 had been assembled at the American aviation 
 bases in France, 984 had been put into service 
 there, and of these 628 were in service at the front, 
 457 being daily in commission. American ma- 
 chines arrived in time to be of great assistance in 
 the St. Mihiel salient offensive and still more so in 
 the Argonne fighting. Looking backward now it 
 is possible to assert positively that this would not 
 have been the case had the decision not been made 
 in May, 1917, to develop and manufacture an 
 American designed engine. 
 
 Much has been written that tends to show that 
 the American forces in France were not sufficiently 
 supplied with airplanes. Some of this is based on 
 the feeling of the infantrymen and artillerymen 
 that a sufficient force would be one that would 
 always prevent the enemy avions from crossing 
 the lines. In this sense our armies were insuffi- 
 ciently supplied, and so were the French and 
 British armies. Besides, as Gen. Peter A. Traub
 
 Origin of the Liberty Engine 73 
 
 remarked in telling of the work of the Thirty- 
 fifth Division in the Argonne fighting, "the 
 air is a very large place." Right up to the end 
 of the war, the German air service was, all things 
 considered, about on a par with that of the Al- 
 lies. There is competent authority, though, for 
 the assertion that from a military organization 
 point of view the supply of aerial forces kept pace 
 with the expansion of the American fighting forces 
 in France. Confessedly, this is a statement that 
 the public will receive with skepticism, but it 
 should be remembered that it does not apply to 
 the subject of territorial bombing operations, but 
 only to the combat equipment of armies. The 
 public looked upon the possibilities of bombing 
 operations against enemy territory as of greater 
 importance than direct aerial military activities. 
 Army men largely took the opposite point of view. 
 If the latter is the correct one the general inference 
 from statements made by our aviation officers is 
 that notwithstanding all delays in production as 
 compared with program, the delivery of the equip- 
 ment kept pace with the development of our armies 
 at the front. That most of the airplanes were sup- 
 plied by the French up to the signing of the armis- 
 tice does not detract from the importance of the 
 fact, for as with artillery and other equipment, the
 
 74 Wings of War 
 
 general program counted on the French filling the 
 gap until America could get into production with 
 the machines that were novel to her manufac- 
 turers. Thus it appears that notwithstanding the 
 failure of the French to make deliveries according 
 to schedule, they did come as fast as our armies 
 grew. Lieut.-Col. Lewis H. Brereton (Chief 
 of Air Service Operations, U. S. A.), positively 
 states that "the air service organization at 
 the front was at all times abreast of the require- 
 ments of the armies at the front." He further 
 says: 
 
 "At the cessation of hostilities, we had a total 
 of forty-seven squadrons in active service on the 
 front, eleven of which were equipped with the 
 American 'plane and Liberty motor. The total 
 number of 'planes in our forces on the front at this 
 time was eight hundred and sixty. The total 
 number of Allied 'planes on the Western front has 
 been estimated as from fifty-five hundred to sev- 
 enty-five hundred. I believe that seven thousand 
 is more nearly correct. Various estimates have 
 placed the German effective strength as between 
 thirty-five hundred and four thousand on the 
 Western front. These figures apparently give us 
 an enormous preponderance of air service over the 
 Western front. Actually, however, conditions were
 
 Origin of the Liberty Engine 75 
 
 such that we were at all times in an area of active 
 operations opposed by an air sendee which com- 
 pared very favorably with ours in strength and 
 efficiency."
 
 CHAPTER IX 
 
 BIRTH OF THE LIBERTY ENGINE 
 
 ONCE the conception of an American standard- 
 ized motor of power possibilities that would keep 
 it in the field for two or three years or longer was 
 crystallized it won almost immediate favor in the 
 higher aircraft circles. The idea was in accordance 
 with the views of all the foreign aviation missions 
 then in America, at least so far as the phase of 
 standardization and large power was concerned. 
 Even though they strongly favored their own 
 evolving engines of high power they could but see 
 in the proposed new motor one more candidate 
 for the final honors. There was no reason why 
 America should not try to create the desired 
 engine. The new idea promised action, and as 
 the engine is the major factor in aircraft construc- 
 tion, it also promised a solid foundation for the 
 whole future structure of the program. It was as 
 a beacon in the darkness. 
 
 Having firmly grasped the idea of an engine 
 76
 
 Birth of the Liberty Engine 77 
 
 which should develop greater power than-*any 
 other proved engine in the field, the next thing for 
 Mr. Deeds to do was to find the engineers who 
 would sympathetically receive the suggestion and 
 faithfully carry it out along the lines he laid down. 
 These were: (i) that it must be light in propor- 
 tion to power; (2) that it must embody no theory 
 or device that had not already been proved in 
 existing engines, and (3) was to keep away from 
 all experimentation and be adaptable to quantity 
 production. It was not to be an invention, but 
 the simplest and most powerful composite of the 
 best known practice. 
 
 The selection of engineers who were equal to the 
 task was vital. In the first place it was thought 
 that they must be engineers who were not only 
 familiar with aeromotors but also men who were 
 familiar with production processes and require- 
 ments. Various men were suggested and discussed 
 and the choice finally fell on J. G. Vincent, chief 
 engineer of the Packard Motor Car Company, and 
 E. J. Hall, of the Hall-Scott Motor Car Company. 
 The choice proved to be an inspiration. Mr. 
 Vincent was already a believer in the idea of a 
 standardized engine with a maximum of inter- 
 changeable parts and a power development accord- 
 ing to the number of primary units an engine
 
 78 Wings of War 
 
 which might conceivably in the end give us but 
 one basic type for all the fixed-cylinder engines 
 the program might require. He had developed 
 experimentally at the Packard works, during two 
 years of painstaking research and effort, an engine 
 that he thought would about meet such require- 
 ments. He was ambitious to have his engine 
 adopted as the American engine, and he was in 
 Washington for that purpose. Mr. Vincent was a 
 highly educated and trained engineer and was as 
 familiar with German and other foreign aviation 
 engine development as any other engineer in Ameri- 
 ca. Taking the German Mercedes as his starting 
 point he had developed powerful automobile racing 
 engines and several aviation motors. He brought 
 to the task the special equipment of the engineer 
 learned in the theory of design and the technique 
 of his profession. He was subjected to the severe 
 test of having the motors he had fathered rejected 
 as too heavy and otherwise unsuited for the pur- 
 pose in view, and being at the same time required 
 to sit down with another engineer to design a com- 
 posite machine that would be better than his own 
 and yet would not be exclusively his. He met the 
 test in a whole-souled, patriotic manner. 
 
 Mr. Hall was a fitting foil for Mr. Vincent. 
 If the latter was an engineer of thought and theory,
 
 Birth of the Liberty Engine 79 
 
 the former was one of work and practice. The 
 one was learned in a scientific way, and the other 
 was learned empirically. Mr. Vincent had ac- 
 quired his knowledge through the eye; Mr. Hall 
 had acquired his through his hands. The former 
 arrived at his objectives by calculation ; the latter 
 by feeling his way. If Mr. Vincent was the 
 scholar-engineer, Mr. Hall was the mechanic-en- 
 gineer. The latter had had more experience in the 
 actual designing and production of aerial engines 
 but the former had had a more extensive engineer- 
 ing association with the best American quantity 
 production processes. Mr. Hall had to submit 
 to the fate of being told that the 12-cylinder 
 engine which he had developed was too heavy for 
 the purpose in view, which was to get a motor 
 of about 225 H. P. and eight cylinders with less 
 than two pounds of weight per unit of H. P. Like 
 Mr. Vincent he took the adverse decision and the 
 new instructions in good part. 
 
 Mr. Vincent had arrived in Washington about 
 the time Mr. Deeds had made his great decision 
 and Mr. Hall had just left for San Francisco. A 
 telegram caught him at Cleveland and turned him 
 back. The two men who were to find the way out 
 of the aviation wilderness were brought together 
 in suite 201, Willard Hotel, Washington, on the
 
 8o Wings of War 
 
 afternoon of Saturday, May 29, 1917. The objec- 
 tive was explained to them carefully and they were 
 facetiously told that they would be shut up to- 
 gether until they produced what was required of 
 them and that the first one who reached out for 
 some pet original idea or any untried principle 
 would "have his hand taken off." They were 
 strangers, never having met until the great en- 
 gineering task of the aerial side of the American 
 effort in the war was laid before them. Mr. Deeds 
 knew that between them they had the peculiar 
 combination to achieve the purpose. Both were 
 in a receptive mood that afternoon, and to lose no 
 time Messrs. Deeds and Waldon went out and got 
 drafting boards and carried them themselves to 
 the room with the twin beds where the two en- 
 gineers were to live until they had evolved the com- 
 ing engine. J. M. Schoonmaker, Jr., an engineer 
 known to Mr. Deeds, happened to be encountered 
 on the street by the latter, and although he was 
 on his honeymoon, was drafted from his bride 
 and commandeered as a temporary draftsman. 
 K. M. Zimmerschied, metallurgist of the General 
 Motors Company, was in Washington and was 
 immediately called to assist. The two engineers 
 began at once to compare opinions, exchange 
 views, discuss general principles, and begin making
 
 Birth of the Liberty Engine 81 
 
 layouts. The first session lasted all the afternoon, 
 all the night, and until 2 o'clock Sunday morning. 
 And, so, tensely the creative work went on for 
 five days. Whatever was required was furnished 
 on the spot. It was regarded as a race against 
 time. At midnight of the first day Dr. Stratton 
 of the Bureau of Standards was brought to the 
 hotel to be asked to provide room for the drafts- 
 men who would elaborate the layouts, which he 
 gladly consented to do. When the decision was 
 communicated to the aviation representatives of 
 the foreign governments then in Washington that 
 the United States was seeking to produce an engine 
 that would be freely given to the Allies they unhes- 
 itatingly brought out the confidential drawings and 
 specifications they had of foreign engines, and 
 Messrs. Vincent and Hall had the benefit of all 
 they contained. During these momentous days 
 other engineers came, conferred, offered their sug- 
 gestions, and departed. 
 
 The main decisions on which the two engineers 
 early agreed was that the new engines should be 
 built around 5x7 individual steel cylinders, with 
 aluminum piston, forked connecting rods, and a 
 direct-drive propeller. This size of cylinder was 
 adopted because both the Hall-Scott Company 
 and the Curtiss Company had found it the most
 
 82 Wings of War 
 
 satisfactory after much experience and because 
 Major Tulasne of the French mission was just then 
 informed that the new Lorraine-Dietrich engine 
 then coming out in France had cylinders of approx- 
 imately that size. 
 
 The end of five days of concentrated effort found 
 the engine designed in the main. After that it was 
 a draftsman and mechanic's job, so far as the first 
 engines were concerned, except that the design was 
 passed in review by eminent motor engineers, who 
 proposed some changes. Copies of the first draw- 
 ings were sent to such men as H. M. Crane, chief 
 engineer of the Wright-Martin Company, who had 
 wrestled with the American adaptation and pro- 
 duction of the Hispano-Suiza Motor; David 
 Fergusson of the Pierce- Arrow Company; D. Mc- 
 Call White of the Cadillac Motor Company, who 
 had been associated with the Napier Company in 
 England, and Fekete of the Hudson Motor Car 
 Company. These men were chosen because of 
 their ability and experience and because they were 
 neither "professorial" theorists nor "mentally 
 dishonest." They thought straight and consis- 
 tently. They were told to find every possible 
 fault they could and make every possible sugges- 
 tion that would be in harmony with the general 
 design. As Colonel Deeds well says: "It was
 
 Birth of the Liberty Engine 83 
 
 important at this time to protect the poor engine 
 from the professor, the theorist, and the would-be 
 engineer. It was an engine based on practice on 
 what had been done and it must be kept so." 
 This statement evinced no disrespect for the sci- 
 entific engineer or the technical man, but an engine 
 that was based on proved practice would have suf- 
 fered had any new theory been applied to it. 
 
 This is really why there was no such doubt about 
 the success of the motor in the minds of those who 
 were early acquainted with its nature, as the pub- 
 lic may have felt. It was not only an engineer's 
 engine and an aviator's engine with all engineer- 
 ing ventures left out, but it was also which was 
 of vital importance a producer's engine; for 
 before the first engines were built, such masters of 
 production as Henry Ford and his associates, 
 Beall and Roberts of the Packard Company, 
 Leland and Lang of the Cadillac, and Chrysler of 
 the Buick were brought into consultation. 
 
 There was nothing magical or revolutionary 
 about the Liberty motor. Its essential planning 
 in such a short time was wonderful, but the two 
 able engineers who put it together from the world's 
 best in such a dramatic manner were not origi- 
 nating or making any revolutionary innovations. 
 Secrecy regarding its design was necessary, and
 
 84 Wings of War 
 
 secrecy means mystery and a mystery is apt to 
 be conjectured to be a miracle. It was a marvel 
 but not one of fortuitously successful engineering 
 venture into the unknown. The "insiders" fully 
 understood this. The public and even some of the 
 outside experts did not. Thence arose much well- 
 meant criticism, the burden of which was that our 
 aviation authorities had staked all on a novel 
 motor that it would take months to develop and 
 that might then be a failure, while there were tried 
 and approved engines that could be put into pro- 
 duction at once. The fact was that they had not 
 staked all on the Liberty motor, that they were 
 seeking to utilize the high-power foreign engines 
 that were available, that only one of them was in 
 production abroad, and that the foreign engines of 
 lower power that were put into production in this 
 country had to be enlarged later. As will be shown 
 farther on, the demand for increased power was 
 so great that initial production of the Liberty 
 itself had to be shifted from the 8- to the 12-cylin- 
 der, and the power of the latter in turn stepped up 
 to keep up with or ahead of the demand thus 
 delaying production to be certain of meeting the 
 purpose of production.
 
 CHAPTER X 
 
 MAKING THE FIRST LIBERTY MOTORS 
 
 EVEN after the grand decision was made, the 
 two engineers had done their basic work, and 
 the drawings were being made yes, even after the 
 first sample motors were made and production had 
 been ordered, it was no easy matter to hold to the 
 purpose. Skepticism among the uninformed was 
 almost universal and Colonel Deeds, Colonel 
 Waldon, and their associates were implored to 
 abandon their course before it was too late. Criti- 
 cism soon became rampant, and the more so, as 
 with each passing day the confidence of the re- 
 sponsible men in the Liberty motor increased, with 
 a consequent tendency to centralize effort on it to 
 the exclusion in some degree of the other possible 
 motors. Time was the great desideratum, action 
 was imperative. So, the first decision to create a 
 new motor was followed by the audacious one a 
 really critical one to proceed with production 
 immediately. In fact the one blended rapidly into 
 
 85
 
 86 Wings of War 
 
 the other. It is not too much to say that this was 
 one of the great decisions of the war. It was cour- 
 ageous beyond belief. It revealed the fact that 
 aircraft production had found a leader. Its luster 
 is in no wise dimmed by the subsequent delays in 
 realizing production in large quantities as early 
 as promised. 
 
 Similar and other delays would have attached to 
 any motor that might have been taken up at that 
 time. Colonel Deeds and his associates and the man- 
 ufacturers may perhaps be justly blamed for their 
 aspiring programs, but they were striving to meet 
 the requirements of a volume of production that 
 was determined by the size of the aviation arm, 
 with the purpose of putting that arm into the field 
 full-fledged in the spring and summer of 1918. It 
 was put up to them to do the impossible, they 
 firmly believed that they could do it, they said 
 they could do it. It was a day when men, hot with 
 the urge of patriotism, of self-sacrifice, had deleted 
 the word "impossible" from their dictionaries. 
 If the general staff wanted something in six 
 months, it declared that it must be done in four, 
 and the aircraft managers persuaded the manu- 
 facturers that it could be done in three, and the 
 latter promised that it would be done in two. 
 These underestimates of the time required to do
 
 The First Liberty Motors 87 
 
 the work led to disappointments but it can be 
 said for them that they had the effect of arousing 
 determination and stimulating effort all along the 
 line. The mark set was unfortunately impossible 
 of attainment but the actual achievement was 
 made extraordinarily remarkable because of the 
 superhuman requirements. 
 
 Even as the drawings were being snatched from 
 the hands of the feverishly toiling draftsmen and 
 despatched to the tool room of the Packard Motor 
 Company, verbal orders were given to the manu- 
 facturers to get ready for production. In those 
 days the business men who had come into the 
 organization had not learned the devious and time- 
 killing routines of government methods. They 
 acted for the country as they were accustomed to 
 act for themselves. They decided swiftly and tele- 
 phoned, telegraphed, and talked orders. The first 
 small motor had not arrived in Washington before 
 there was the lively activity of great preparation 
 in the plants that were to undertake the work, 
 and one colossal plant that of the Lincoln Motor 
 Company was started from the grass-roots. The 
 making of the first engine was as composite as 
 its designing. 
 
 The parts for the first engine were made in 
 various plants as follows:
 
 88 Wings of War 
 
 The General Aluminum & Brass Manufacturing 
 Company of Detroit made the bronze-back, bab- 
 bit-lined bearings. 
 
 The Cadillac Motor Car Company, of Detroit, 
 made the connecting rods, connecting-rod upper- 
 end bushings, connecting-rod bolts, and rocker-arm 
 assemblies. 
 
 The L. O. Gordon Manufacturing Company, of 
 Muskegon, made the cam shafts. 
 
 The Park Drop Forge Company, of Cleveland, 
 made the crank-shaft forgings. These forgings, 
 completely heat-treated, were produced in three 
 days, because Mr. Hall gave them permission to 
 use his dies. 
 
 The crank shafts were machined at the Packard 
 factory. 
 
 The Hall-Scott Motor Car Company, of Ber- 
 keley, Cal., made all the bevel gears. 
 
 The Hess-Bright Manufacturing Company, of 
 Philadelphia, made the ball bearings. 
 
 The Burd High Compression Ring Company, 
 of Rockford, 111., made the piston rings. 
 
 The Aluminum Castings Company, of Cleve- 
 land, made the die-cast alloy pistons, and ma- 
 chined them up to grinding. 
 
 The Rich Tool Company, of Chicago, made the 
 valves.
 
 Woman Operator Machining Cylinders of Liberty Motors (at the 
 Cadillac Plant, Detroit). The War Emergency Necessi- 
 tated the Employment of Thousands of Women in 
 the Aircraft Industry
 
 The First Liberty Motors 89 
 
 The Gibson Company, of Muskegon, made the 
 springs. 
 
 The Packard Company made all the patterns, 
 and the aluminum castings were made by the Gen- 
 eral Aluminum & Brass Manufacturing Company. 
 
 The Packard Company used many of its own 
 dies in order to speedily obtain suitable drop forg- 
 ings, and also made new dies. 
 
 The carburetors were supplied by the Zenith 
 Carburetor Company of Detroit. 
 
 The ignition apparatus was made by the Delco 
 Company of Dayton, Ohio. 
 
 The Packard Company produced all the other 
 parts. 
 
 As fast as completed these parts were assembled 
 in the laboratory of the Packard Motor Company 
 in Detroit and the first complete engine arrived in 
 Washington on July 3d just thirty-five days after 
 the decision that it should be born. Every part 
 went into its proper place without difficulty. The 
 engine an eight-cylinder was kept in the draft- 
 ing room as a life-size model and was never tested. 
 The second eight-cylinder was completed two 
 weeks later and passed severest tests. The first 
 twelve-cylinder was next rushed to completion and 
 had successfully passed its 5O-hour stand test by 
 August 25, 1917.
 
 90 Wings of War 
 
 This test removed the last shred of doubt that 
 might have lingered in the minds of the managers 
 and the experts who were acquainted with its 
 results. From this time on production was the one 
 consideration. The practical manufacturers who 
 were to make the new machine in record-breaking 
 quantities were given every opportunity to sug- 
 gest changes that would facilitate production and 
 detect any lingering "bugs" that might still be 
 harbored in the new motor. All of them received 
 the new creation with enthusiasm, and none of 
 them ever doubted its success even in the most 
 trying days of changes and fault-finding that were 
 to follow. They were veterans in development and 
 production and they knew that troubles were ahead 
 of them, but they never for a moment doubted 
 that they would be surmounted successfully. 
 
 At first it was planned to have a very large pro- 
 portion of eight-cylinders in the first orders. In 
 fact, an order for ten thousand of them was placed 
 with the Ford Motor Company, and if that order 
 had stood there is little doubt that volume pro- 
 duction would have been reached within six 
 months. But so rapidly were things evolving and 
 moving forward at the front, that within a month 
 it became evident that the 225 H. P. of the eight- 
 cylinder was not enough to meet the major require-
 
 The First Liberty Motors 9 1 
 
 ment of the times. So, this order, on advice from 
 the front, was canceled and all efforts were con- 
 centrated on the 12-cylinder. Subsequent events 
 showed that so sweeping a change was a mistake. 
 It turned out that the wisest observers at the 
 front did not themselves know which way they 
 were going. The requirements did call for more 
 and more large motors, but the turn of favor 
 toward the single-seater left ample room for large 
 numbers of engines from 200 to 300 H. P. This, 
 however, was not the business of the producers. 
 Their business was to produce what the front 
 demanded. 
 
 The original order for 22,500 motors was dis- 
 tributed as follows : 
 
 Packard Motor Car Company 6000 
 
 Lincoln Motor Company 6000 
 
 Ford Motor Company 5000 
 
 Nordyke & Marmon 3000 
 
 General Motors Corporation (Buick and 
 
 Cadillac) 2000 
 
 Trego Motors Corporation 500 
 
 The criticism was immediately forthcoming that 
 automobile makers instead of aircraft manufac- 
 turers were entrusted with the task. If we had 
 had a group of powerful aeromotor manufacturers 
 in this country the task would naturally have been
 
 92 Wings of War 
 
 theirs. We did not have such a group, and such 
 domestic manufacturers of strength and organi- 
 zation as we had, as well as many of the smaller 
 ones, were already staggering under the loads relat- 
 ing to other parts of the aviation production pro- 
 gram that had been placed on them. All the firms 
 named above were makers of motors and skilled 
 in quantity production. 
 
 They had large and accomplished engineering 
 staffs and they had the "know-how" and the basic 
 facilities of production, and they were to have the 
 advantage of the continuous counsels of Messrs. 
 Vincent and Hall, two of the best aeronautical 
 motor engineers in the country. It is easier to 
 erect buildings and install machinery than it is to 
 create the human organization of successful manu- 
 facturing. Doubtless the engine makers would 
 have been less confident of early results and they 
 would have avoided many difficulties if they had 
 previously been making delicate and precise flight 
 motors. 
 
 Most of them were not eager for the job, except 
 as they were eager to do their part in the war. 
 But all of them were inspired with the same enthu 
 siasm that led "Uncle" Henry Leland in his 
 seventy-fifth year to take a contract to erect a vast 
 new factory the Lincoln and undertake to pro-
 
 Packard Motor Car Company Plant at Detroit. Original Plant and Emergency 
 Extension, Devoted Largely to Liberty Engine Production During the War 
 
 Lincoln Motor Company Plant at Detroit, Rushed to Completion in Record 
 Time for Manufacture of Liberty Engines. Building Erected, Organi- 
 zation of 6,000 Persons Created, and 2,000 Liberty Motors 
 Produced, All in Twelve Months
 
 The First Liberty Motors 93 
 
 duce six thousand motors within a year. It is 
 giving a small measure of credit to say, in passing, 
 that Henry Leland, father of the Cadillac car and 
 company, who is affectionately known as "Uncle" 
 in the American automobile industry, of which he 
 is the acknowledged dean by reason of seniority, 
 was, on account of his patriotic devotion, his man- 
 ufacturing ability and prestige, and his unfailing 
 enthusiasm, a great factor in the Liberty motor's 
 success. 
 
 All worked with energy and concentration, and 
 moreover, with a magnificent spirit of fellowship 
 and cooperation. House pride, trade secrets, and 
 even patent rights were forgotten. It was all for 
 one and one for all. Thus were united in a great 
 manufacturing undertaking the resources, the 
 experience, the engineering ability, and the peculiar 
 specializations of at least five of the most solid, 
 careful, reliable, and efficient manufacturing insti- 
 tutions in America. 
 
 These statements are not mere glittering gener- 
 alities. The spirit of mutual assistance was the 
 spontaneous product of the union of men in a com- 
 mon cause for an unselfish purpose, but it was 
 applied practically and methodically. The man- 
 ufacturers were given to understand that in under- 
 taking the production of the Liberty motor they
 
 94 Wings of War 
 
 had made it their child and that they thereby 
 became as much responsible for it as the engineers 
 and the Signal Corps. It was their business to find 
 its faults either from an engineering or production 
 point of view as well as to make it in great num- 
 bers in record time. They accepted this view, and 
 that they acted on it is proved by the fact that 
 ninety per cent, of all the changes made in the 
 course of production were suggested by them. 
 They pooled their criticisms as well as their 
 resources. They exchanged ideas as well as tools 
 and facilities and even made parts for each other, 
 each plant doing more than its proportionate 
 share of what it was best fitted to. 
 
 This voluntary and irregular but none the 
 less admirable cooperation of the first days was 
 soon reduced to regularity and routine. Lieut. 
 Harold Emmons, who was charged by Colonel 
 Deeds with the supervision of engine production, 
 and performed his functions with signal ability and 
 success, took advantage of this union to apply to 
 production the same idea that had dominated the 
 creation of the Liberty motor, viz., practicality. 
 The engine had been designed without interference 
 from the dreamers and Lieutenant Emmons in- 
 tended to have it produced without obstruction 
 from the perfectists. The current of changes or
 
 The First Liberty Motors 95 
 
 demands for changes by engineers set in early but 
 Lieutenant Emmons soon checked it. His motto 
 was that there is a place for the engineer and a 
 place for the producer and also a place for the 
 engineer to stop and the producer to begin. He 
 was determined that only absolutely necessary 
 changes should be made and that they should be 
 the result of joint agreement by engineers and pro- 
 ducers. In consequence Colonel Deeds issued an 
 order concentrating Liberty motor engineering and 
 production control in the Detroit district, thus 
 taking it away from Washington and from long- 
 distance entangling. Engineering, production, and 
 inspection were all brought together there respon- 
 sibly and ultimately in the hands of a committee 
 of engineers and manufacturers made up of Maj. 
 James G. Heaslet, Henry M. Leland, the Cadillac 
 veteran and the Lincoln motors recruit, C. Harold 
 Wills of the Ford Motor Company, Messrs. Beall 
 and Roberts of the Packard Motor Car Company, 
 D. McCall White, of the Cadillac Motor Company, 
 Walter Chrysler, general manager of the Buick 
 Company, and Lt. Col. E. J. Hall, one of the 
 designers of the engines. Major Heaslet, who was 
 formerly a vice-president of the Studebaker Cor- 
 poration, was in general charge as district manager, 
 and his work in that office was one of the great
 
 96 Wings of War 
 
 executive feats of the war. Five of the six Liberty 
 motor contractors were within a short distance of 
 his office and consultations were easy and fre- 
 quent. Engineering and production thus went 
 together, and the Liberty motor was developed and 
 produced from half a dozen plants by an admir- 
 able system which made them exactly like one 
 great plant producing something new of its own. 
 The head and the body were together. This idea 
 of decentralization into strongly authorized dis- 
 tricts came later to be taken up by the War Depart- 
 ment in most of its activities, but not until the 
 narrow idea of central domination and scrutiny of 
 everything from tacks to transports had badly 
 scrambled production in many lines. 
 
 In this union of all for the common good, the 
 Packard Company became the sacrificial goat, gen- 
 erally speaking. It pushed on a little ahead of the 
 others and they had the benefits of its pioneering. 
 It was mostly the Packard that did and undid and 
 wrought and unwrought.and mapped and scrapped 
 in that considerable degree of development of the 
 new engine that was overlapped with production. 
 The laboratory the Packard Company had estab- 
 lished in connection with Colonel Vincent's two 
 years of research and experimentation peculiarly 
 fitted it for this pioneering work. On the other
 
 The First Liberty Motors 97 
 
 hand, the superb organization of the Ford Motor 
 Company especially adapted it to dealing with 
 peculiar problems of production in regard to the 
 new motor. So, altogether the Liberty motor 
 went into production as auspiciously as it had 
 come out of composition. 
 
 The event proved the wisdom of the conception 
 and the soundness of the design. "In approxi- 
 mately one year from the time it was originally 
 designed," says Maj. L. S. Simons, of the Air 
 Service, "and in spite of the avalanche of criticism 
 during the last six months of that year, it became 
 the standard motor of the American government 
 and, practically, of the Allied governments as well." 
 
 While Messrs. Vincent and Hall were still in the 
 midst of their creative task, Mr. Deeds had asked 
 the Aircraft Production Board for two hundred 
 and fifty thousand dollars for the development of 
 the first five, each, of the eight and twelve engines. 
 The Board was skeptical but quickly granted the 
 funds, and set July 24th as the time limit for the 
 delivery of the first engine. This was on June 4th. 
 The first engine arrived in Washington on July 3d. 
 
 The new motor was at first designated as the 
 American or the United States motor, but Admiral 
 Taylor was the first to call it the "Liberty Motor" 
 and it was thus christened by general consent,
 
 98 Wings of War 
 
 because it was for the world-cause of Liberty and 
 it was no single man or nation's motor. It was 
 eclectic. The chief features of the Liberty motor 
 are officially described as follows : 
 
 Cylinders The design of the cylinders for the 
 Liberty engine followed the practice used in the 
 German Mercedes, English Rolls-Royce, French 
 Lorraine-Dietrich, Italian Isotti-Fraschini, and 
 others, both before the war and during the war. 
 The cylinders were made of steel inner shells sur- 
 rounded by pressed steel water jackets. The 
 Packard Company by long experiment had devel- 
 oped a practical production method of welding 
 together the several parts of a steel cylinder. 
 
 Cam Shaft and Valve Mechanism above Cylinder 
 Heads The design of the above was based on the 
 general arrangement of the Mercedes and Rolls- 
 Royce, but had been improved for automatic 
 lubrication without wasting oil by the Packard 
 Motor Car Company. 
 
 Cam-shaft Drive The cam-shaft drive was the 
 same general type as used on the Hall-Scott, 
 Mercedes, Hispano-Suiza, Rolls-Royce, Renault, 
 Fiat, and others. 
 
 Angle between Cylinders In the Liberty the 
 included angle between the cylinders is 45. 
 This angle was adopted to save head resistance,
 
 The First Liberty Motors 99 
 
 to give greater strength to the crank case, and to 
 reduce periodic vibration. This decision was based 
 on the experience of the Renault and Packard 
 engines with approximately the same angle. 
 
 Electric Generator and Ignition The Delco 
 system of ignition, which had been successfully 
 used on hundreds of thousands of internal com- 
 bustion engines, was adopted, a special design 
 being produced for the Liberty engine to provide 
 a reliable double ignition. 
 
 Pistons The die-cast aluminum alloy pistons 
 of the Liberty engine were based upon extensive 
 research and development work by the Hall-Scott 
 Company under service conditions. 
 
 Connecting Rods The well-known forked or 
 straddle-type connecting rods as used on the De 
 Dion and Cadillac cars, and also on the His- 
 pano-Suiza and other aviation engines, were 
 adopted. 
 
 Crank Shaft The crank-shaft design followed 
 the standard practice for large-bore engines, every 
 crank pin operating between two main bearings as 
 in the Mercedes, Rolls-Royce, Hall-Scott, Curtiss, 
 and Renault. 
 
 Crank Case The crank case followed the design 
 of the Mercedes and Hispano-Suiza, in which the 
 crank case is a box section carrying the shaft in
 
 ioo Wings of War 
 
 bearings clamped between the top and bottom 
 halves by means of long through bolts. 
 
 Lubrication The original system of lubrication 
 combined the features of a dry crank case, such as 
 in the Rolls-Royce, with pressure feed to the main 
 crank-shaft bearings, and scupper feed to crank- 
 pin bearings, as in the Hall-Scott and in some 
 foreign engines. This was subsequently changed 
 to add pressure feed to crank-pin bearings, as in 
 the Rolls-Royce, Hispano-Suiza, and other engines. 
 
 Propeller Hub The propeller hub design fol- 
 lowed such well-known engines as the Hispano- 
 Suiza and Mercedes. 
 
 Water Pump The conventional centrifugal type 
 of water pump was adapted to the Liberty. 
 
 Carburetor The Zenith type of carburetor was 
 adapted for use on the Liberty engine. 
 
 While the engineers and manufacturers who 
 contributed to the Liberty motor engineering and 
 development are entitled to unstinted recognition 
 and there has been some controversy concern- 
 ing the distribution of credit it is but fair to say 
 that to Colonel Deeds is to be assigned credit for the 
 creative concept and decision that there should be 
 a standardized American motor along certain well 
 denned and tried lines. Without that far-reaching 
 decision there would have been no Liberty motor,
 
 The First Liberty Motors 101 
 
 but only adaptations of European designs and, 
 probably, a multitude of individual American 
 designs, which would have resulted in the Babel of 
 engines that cumbered the aviation programs of 
 the Allies.
 
 CHAPTER XI 
 
 LIBERTY MOTOR PRODUCTION 
 
 THE beginnings of Liberty motor production 
 were, indeed, auspicious. In principle and intrin- 
 sically it continued so. Nevertheless, within four 
 or five months the public was fearful that the motor 
 was a failure and was convinced that chaos char- 
 acterized production and engineering. This pub- 
 lic attitude, which resulted in bringing aircraft 
 production into such great disrepute, was based 
 on a misconception and on a failure. 
 
 The misconception was in the inability of the 
 public to grasp the fact that as a necessity of war 
 development and production were coincidental in 
 the case of the Liberty motor, and that even if 
 development could have preceded production, the 
 latter would have revealed the necessity of further 
 alterations. 
 
 The failure was that of not realizing production 
 in accordance with the schedule. 
 
 The public was overwhelmed with adverse criti- 
 
 102
 
 Liberty Motor Production 103 
 
 cisms of the motor itself and its parts and was del- 
 uged with accounts of innumerable alterations. 
 At the same time it was disillusioned as to the 
 celerity with which substantial production could 
 be attained. 
 
 In the ordinary course of bringing out a new and 
 complex mechanism a year or more is devoted to 
 what is known as development. The first machines 
 are tested, experimented with, severely tried, and 
 altered in the light of this experience. The next 
 step is production. But it is invariably found that 
 development must in some degree overlap produc- 
 tion. In other words the most careful preliminary 
 tests and studies do not reveal all the weaknesses 
 or defects. Production is often far advanced when 
 it is found necessary to retrace the steps and make 
 some change that may hold up production on the 
 very verge of shipment or even after shipment 
 has begun. 
 
 The plan imposed by inexorable war upon the 
 aircraft managers and makers was to merge devel- 
 op nent and production. They all knew that they 
 hi d a design that was essentially sound; they all 
 knew that it must be developed by experimenta- 
 tion and they all knew that this development must 
 be coincident with production. This was the only 
 way in which two years could be crowded into one.
 
 104 Wings of War 
 
 It was expensive and tedious, but there was no 
 other way. It involved changes in design and in 
 the strength of parts and the wastage in some 
 degree of parts completed or in process of manu- 
 facture when the changes were found necessary. 
 A third class of alterations was the consequence of 
 an imposed change in the objective. Production 
 began with a 12-cylinder engine of about 330 H. P. 
 Responding to the best advice and judgment this 
 objective was changed during production to 375 
 and finally to 400 H. P. Thus there were three 
 classes of changes : 
 
 First : In design. 
 
 Second : Those necessitated by increase of power. 
 
 Third: Changes in "manufacturing limits." 
 
 It is remarkable that there was only one change 
 of essential design that in only one case was the 
 judgment of Messrs. Vincent and Hall set aside. 
 This was the abandonment of the scupper system 
 of oil "feed" for the pressure system. Either 
 system gave good results but experience showed 
 that the pressure system was better, chiefly 
 because it was "foolproof." This change was not 
 productive of great delays and did not involve the 
 abandonment of the motors completed at the time 
 it was decided upon. 
 
 The changes necessitated by the successive de-
 
 Liberty Motor Production 105 
 
 cisions to increase power were entirely extrane- 
 ous to design. They involved considerable delays. 
 About three hundred 12-cylinder engines were in 
 production when the horsepower was raised from 
 330 to 375. This necessitated strengthening var- 
 ious parts, chiefly the crank shaft. Several hun- 
 dred engines of this power were delivered, when in 
 response to the insistent demand from abroad for 
 still more power the change was made to 400 H. P. 
 This necessitated the strengthening of a large num- 
 ber of the moving parts of the engine, including 
 the crank shaft, connecting rods, bearings, etc. 
 The changes were not only in forrn but were also 
 metallurgical. The greatest difficulty and the most 
 delay of all these power changes related to the con- 
 necting rods. The alteration of so many important 
 parts was a very serious matter, involving as it did 
 changes in a large part of the special tools of which 
 there were about twenty-five hundred different 
 kinds and as many as ninety thousand altogether 
 in a single factory. The changes in equipment 
 involved changes in the engine plants, the forging 
 shops, the parts plants, and so on "clear down the 
 production line to the producers of raw materials." 
 Such sweeping changes were inevitably produc- 
 tive of disconcerting delays. In the last analysis 
 they were imposed by the trend of aerial warfare
 
 106 Wings of War 
 
 as determined by those in authority at the front. 
 It is a moot question whether the additional power 
 was worth the retardation of production that fol- 
 lowed. It might have been better to have had two 
 thousand 330 H. P. engines in May, 1918, instead 
 of eleven hundred 400 H. P. This presumptive 
 advantage was, however, in fact offset by the 
 greater delays in the production of the 'planes that 
 were to receive the engines. Even with the delays 
 imposed from without the motor manufacturers 
 arrived ahead of the 'plane makers. 
 
 The most numerous changes, those relating to 
 manufacturing limits, were but trivial in their 
 effect on production. As a rule they were changes 
 in dimensions that tended to facilitate production 
 rather than to delay it, though they kept the 
 .draftsmen and the tool-makers busy. They were 
 portentous in numbers but harmless or helpful to 
 speed of production. 
 
 The outstanding fact in regard to change is that 
 the actual delays in production resulting from 
 driving development and production together were 
 insignificant. Had the original power limits been 
 maintained production would have come much 
 closer to the impossible schedule. The outcome 
 fully justified the decision to put the new engine 
 into production regardless of development. In
 
 Assembling Liberty Motors at the Plant of the Lincoln Motor Co. 
 
 Section of Track System for Machining Upper Half of Liberty Motor Crank 
 Case, Lincoln Motor Co.
 
 Liberty Motor Production 107 
 
 truth the experience with the Liberty motor in this 
 respect was marvelous. It is commonly lost sight 
 of in the shadow of the grand total of delays, but 
 it is essential to keep it in mind, as it completely 
 refutes the criticism so thickly showered upon the 
 aircraft managers that they had made a vital mis- 
 take in taking up the production of a new engine 
 on a large scale. 
 
 Altogether outside of the delays that resulted 
 from the three classes of alterations, production 
 fell behind schedule for many reasons, most of 
 which flowed from the lack of comprehension of 
 all concerned of the sweeping changes that war had 
 wrought in all industrial conditions and because of 
 the failure of the manufacturers to perceive how 
 much more difficult and laborious was the making 
 of a high-power aerial engine than that of an auto- 
 mobile engine. One of the Liberty motor makers 
 is on record as saying that it was their optimism 
 as to their ability to achieve that deceived them- 
 selves and the whole aircraft organization. This 
 optimism was unfailing and continued to the last. 
 The aim was high, but so also was the hit. 
 
 But when these facts are admitted, the other 
 fact must also be conceded that with all its delays 
 piled on delays the delivery of eleven hundred com- 
 pleted engines within one year from the day that
 
 io8 Wings of War 
 
 the first pencil was put to paper in the beginning 
 of design was a truly remarkable performance. 
 It was matched in no other country during the war. 
 
 Even with the simpler manufacturing processes 
 of Europe, we have the authority of the British 
 war cabinet for the statement that experience shows 
 that as a rule, from the date of conception and 
 design of an aero engine "to its delivery in series 
 by the manufacturer more than a year elapses." 
 
 Let us consider the difficulties that strewed the 
 path of the makers of the Liberty engine. In the 
 first place, existing plants did not have machinery 
 of adequate size to handle the parts of the Liberty. 
 This necessitated the building and sometimes even 
 the designing of new machines. These machines 
 required, in turn, from twenty-five hundred to 
 three thousand different tools, jigs, and fixtures, 
 which, according to the size of the plant, had to be 
 multiplied many times. The making of the im- 
 mense number of tools took a longer time than 
 was allotted. Tool-makers were scarce and there 
 was a tremendous demand for their services and of 
 the tool-making shops for many other war pur- 
 poses. Then it developed that men who had done 
 very well as automobile engine mechanics were not 
 possessed of the skill required for work on the 
 Liberty motor. They had to be re-trained or
 
 Liberty Motor Production 109 
 
 replaced by thousands of men and women specially 
 trained for the work. Many skilled men were 
 drafted into the military service. It was difficult 
 to obtain the high grade of materials required for 
 such a light and powerful machine as the Liberty 
 engine, which has twenty-five per cent, less weight 
 than a 12-cylinder automobile engine and generates 
 four times as much power. Then there were ex- 
 ceptional fuel and power shortages and distress- 
 ing failures of railway transportation in 1917 and 
 1918. It is easy to mention these difficulties but 
 hard to appreciate them. They were so baffling 
 that more than one overworked and over worried 
 executive, who found all his well-conceived plans 
 and arrangements thrown into an absolute chaos 
 wherein order gave way to disorder and routine to 
 a succession of the unexpected, broke down and 
 quit his post in despair. 
 
 In the face of all difficulties production from 
 machine tools began in December, 1917, with twen- 
 ty-two engines and gradually grew to 620 in the 
 following May; 1 102 in June; 1589 in July; 2297 in 
 August ; 2302 in September, and 3878 in October. 
 Up to November 29th, eighteen days after the 
 armistice was signed, the total production of 
 Liberty motors was 15,572, and it eventually 
 reached 20,478, equivalent to more than eight mil-
 
 no Wings of War 
 
 lion H. P. When the war ended the Liberty engine 
 program had been extended to 56,100 of the 12- 
 cylinder and 8000 of the eight, thus giving the power 
 that insured air control to the Allies. This enlarged 
 program was necessary to meet the growing require- 
 ments of our army and navy and of the Allies. The 
 British required 5500; the French counted on tak- 
 ing twenty per cent, of the entire output and the 
 Italians were planning to take a large quantity. To 
 meet this increased demand new orders had been 
 placed with the plants then engaged in Liberty 
 engine production and with the Willys-Overland 
 plants at Toledo and Elyria, O., and Elmira, N. Y., 
 and with the Olds Motor Company, at Lansing, 
 Mich. Of the completed engines (as of Novem- 
 ber nth), 5323 were delivered to airplane manu- 
 facturers for installation in airplanes; 4511 were 
 sent directly to the A. E. F. in France; 3742 were 
 delivered to the navy; 1089 were sent to the Allies 
 and 907 to the training fields. When John D. Ryan, 
 as Assistant Secretary of War in charge of the air 
 service, was abroad in September, 1918, he prom- 
 ised the French 1500 engines by December 3ist 
 and 750 a month during the first six months of 
 1919. The British were promised an additional 
 thousand a month during the early months of the 
 same year.
 
 Liberty Motor Production m 
 
 An idea of the volume of production already 
 attained may be received from the fact that in 
 October the output of Liberty motors was at the 
 rate of 150 a day for every working day in the 
 month, whereas the rate of production of its near- 
 est rival in size that ever got into real production 
 the Rolls-Royce was ten a day, though the Rolls- 
 Royce was in production years before the Liberty 
 was dreamed of. During 1919 the rate of produc- 
 tion would undoubtedly have passed two hundred 
 a day, sufficient to have supplied the Allied armies 
 with an amount of aerial power that was beyond 
 the remotest possibility of German production. 
 // is hardly necessary to add that the record made in 
 the production of Liberty engines has never been 
 even remotely touched in the production of any 
 like complex mechanism. Indeed no other motor 
 program than its own ever surpassed this actual 
 achievement. 
 
 It is one of the bitter ironies of history that the 
 men who were responsible for the great decision 
 that gave us the Liberty engine have so far had 
 little honor and much obloquy. The public tried 
 and condemned them and the manufacturers early 
 in the war and years may elapse before they will 
 get their dues. One of them, Colonel Deeds, the 
 man who took the responsibility of decreeing the
 
 Wings of War 
 
 Liberty motor, was even in the shadow of court- 
 martial for a time and had to submit to the humili- 
 ation of a temporary detachment from duty just 
 at the moment when his decision and his labors 
 were meeting their recognition in manufacturing 
 and military results. It was much as if General 
 Pershing had been relieved from duty while the 
 victorious guns of St. Mihiel were still thundering 
 the proof of his victory. 
 
 It is an illuminating commentary on the dis- 
 couragements that were set in the way of the 
 designers and producers of the Liberty engine that 
 it is a common saying in aircraft circles that for- 
 eigners had to "sell" it to us, meaning that it was 
 appreciated abroad at its true worth before it 
 received general recognition at home. Brig. Gen. 
 J. D. Cormack of the British War Mission in 
 America, in a speech at the Army and Navy Club, 
 Washington, December 20, 1918, said: "An aero- 
 plane is much more complicated than it looks. It 
 is built around an engine, and the manner in which 
 you buckled to and produced a really good engine 
 is, in my opinion, the finest feat in design and pro- 
 duction that has been accomplished during the war 
 so far as aircraft matters are concerned. You 
 know the history of the Liberty engine and its 
 fine performances in aeroplanes and flying boats
 
 Liberty Motor Production 113 
 
 and you will appreciate how greatly you and all the 
 Allies have to thank Colonel Deeds for his efforts 
 in connection with its design and production." 
 
 The British Air Ministry adopted the Liberty 
 engine "in the first line of high-powered engines" 
 in June, and in September, 1918, it reported that 
 in the same 'planes the Liberty did at least as well 
 as the Rolls-Royce. Berkight, designer of the 
 French Hispano-Suiza engines, stated that the 
 Liberty motor was superior to any high-powered 
 engine developed on the continent. 
 
 The Liberty engine, it must be remembered, is 
 not only a great aerial motor and the best high- 
 power motor that has so far been produced, uniting 
 a minimum of weight with a maximum of power, 
 but it is a quantity production motor. It was 
 believed in Europe that American automatic 
 machine methods of manufacture along standard- 
 ization lines could not be successfully applied to so 
 delicate and precise a mechanism as an aerial 
 motor. American manufacturing processes have 
 therefore achieved a brilliant feat, for they suc- 
 ceeded in pouring out of their factories, in an un- 
 ending procession, motors that are the equal of 
 the carefully hand-made engines of Europe. It is 
 these engines, each simply one of a quantity and 
 without individual tuning and perfecting, that are
 
 ii4 Wings of War 
 
 now filling the aviation world with accounts of 
 their triumph. It was simply a Liberty motor 
 installed in a De Haviland 4, also a quantity pro- 
 duction structure, in which Capt. E. F. White 
 made the first non-stop flight, on April 19, 1919, 
 from Chicago to New York in six hours and fifty 
 minutes, a distance of 727 miles. It was simply 
 another regular Liberty motor and another De 
 Haviland 4 which Captain Theodore C. McCauley 
 used in his record-breaking flight in the same 
 month from Tuscon, Ariz., to Stillwater, Texas, 880 
 miles in a little over eight hours, making the then 
 world's non-stop record flight. In both cases the 
 motors performed perfectly throughout the long 
 hours of tremendous strain. The supreme triumph 
 of the Liberty motor came when Commander 
 Read, U. S. N., in the navy flying boat NC-4, 
 equipped with four Liberty motors (high com- 
 pression), completed the first aerial crossing of the 
 Atlantic, May 27, 1919. It was a DH-4 driven 
 by a Liberty motor in which Lieutenant Maynard 
 won the transcontinental airplane race from New 
 York to San Francisco and return. All of these 
 engines were regular "run-of -factory" standard, 
 quantity-production machines. 
 
 These achievements and many others of note 
 are the final and sufficient answer to the indict-
 
 At Work on Liberty Engine Parts at the Packard Plant
 
 Liberty Motor Production 115 
 
 ments made against the Liberty in its embryonic 
 days. The American aircraft managers set out to 
 design an air motor of great power that was sus- 
 ceptible of quantity production by the character- 
 istic American methods of machine-tool utiliza- 
 tion and standardization of parts. The attained 
 rate of output of 150 a day justified the ambi- 
 tion to obtain quantity production; the brilliant 
 and solid performances of individual motors on 
 land and sea and under every condition of weather, 
 climate, and altitude 1 demonstrate that reliability 
 and efficiency were not sacrificed in obtaining 
 quantity. 
 
 'It was in an American built Lepere biplane driven by a 
 Liberty engine that Major R. W. Schroeder made the world's 
 altitude record, 36,020 feet, at Dayton, Feb. 26, 1920.
 
 CHAPTER XII 
 
 INCIDENTS OF LIBERTY ENGINE PRODUCTION 
 
 THE development of production of the Liberty 
 motor was accompanied by many interesting and 
 ingenious methods of speeding up manufacture. 
 Each of the six companies to whom production 
 was confined at the moment of the ending of the 
 war, has its own collection of industrial adventures 
 and achievements in connection with the work, 
 which will become house traditions. Whatever 
 anyone discovered immediately became the prop- 
 erty of all. The Packard Company pioneered and 
 sacrificed itself for all and discovered many mas- 
 teries of efficient production, but perhaps the most 
 spectacular innovation was the triumph of the 
 Ford Motor Company in cylinder forgings. 
 
 The enormous number of steel cylinders that 
 would be required for the first Liberty motor order 
 of 22,500 machines, which, allowing for spares and 
 wastage, would run to more than three hundred 
 thousand, was dismaying to the aircraft managers 
 
 116
 
 Liberty Engine Production 117 
 
 and was the one feature that gave them pause in 
 their early optimism. Hitherto, the light, thin 
 steel aircraft motor cylinders had been bored out 
 of and lathed down from solid steel forgings. A 
 forging weighing 140 pounds was thus reduced to 
 a finished cylinder weighing only seven pounds. 
 The process was tedious and laborious. The need 
 was for two thousand cylinders a day when pro- 
 duction was in full blast. Anything less meant 
 retarded output. 
 
 Colonels Deeds and Waldon decided to take the 
 problem to the Ford Motor Company because of 
 its extensive resources, experience, facilities, and 
 special achievements in forgings. Taking with 
 them three wooden blocks representing the size 
 and shape of the forgings from which the cylinders 
 were then being made, and one finished cylinder, 
 they called on Henry Ford one Sunday afternoon at 
 his home in Dearborn, near Detroit, and appealed 
 to him for help. The manufacturing crisis inter- 
 ested Mr. Ford. He offered all the ingenuity of 
 his organization to meet it. The next day the two 
 officials met again with Mr. Ford at the offices of 
 the Ford Motor Company. With them were 
 Messrs. Mayo, Wills, Knudson, and Edsel Ford of 
 the Ford staff and also Henry M. and W. C. Leland 
 of the Lincoln Motor Company; C. F. Kettering,
 
 ii8 Wings of War 
 
 the Dayton automotive engineer, associated with 
 the Dayton- Wright Aircraft Company ; F. F. Beall 
 and Edwin F. Roberts of the Packard Company 
 and E. J. Hall, one of the designers of the Liberty 
 motor. It was one of the strongest assemblages 
 of engineering and productive ability that could 
 have been brought together in America. Four 
 suggestions came out of the conference then the 
 meeting adjourned and the whole matter was left 
 to Henry Ford. 
 
 Three weeks later Mr. Mayo, of the Ford Com- 
 pany, walked into Colonel Deeds' office in Wash- 
 ington with a cylinder forging, made, he said, by 
 a method that yielded unhoped-for speed. One 
 glance at the forging and Mr. Mayo's assurance 
 was enough. Instantly Henry Ford was called on 
 the long distance and asked if he would start at 
 once to make two hundred thousand cylinders. 
 
 "Yes," was the answer. 
 
 And the thing was as good as done. 
 
 Letters, contract, and prices followed later. It 
 was the big business way of the big business men 
 who were running things in those days. After 
 manufacture had been proceeding long enough to 
 estimate costs, Mr. Ford fixed the price at seven 
 dollars a cylinder. The cost by the other method 
 was about twenty-five dollars.
 
 Liberty Engine Production 119 
 
 Without waiting for further authority the Ford 
 people moved from their plant in Windsor, on the 
 Canadian side at Detroit, one of the enormous 
 presses they had there the largest machines of 
 the kind ever built. Then they tore out all their 
 regular installations in a whole vast section of their 
 plant and turned their heaviest machinery on to 
 the cylinder job. Money was spent without stint 
 and men worked without saving themselves to 
 rush this installation to conclusion. 
 
 The process was unique. It consisted of taking 
 steel tubing of the requisite diameter and cutting 
 it up obliquely. This oblique slice supplied the 
 material for closing the valve-head end of the 
 cylinder. The sections corresponding to the cylin- 
 ders that were to be were then put through the 
 requisite heat treatment and forging. The result- 
 ing forgings were not very much heavier than the 
 cylinders that were eventually ground down from 
 them. Almost from the start of this process the 
 Ford Company turned out hundreds of cylinders 
 a day, against a maximum of 151 by the old process 
 and was soon making as high as two thousand a 
 day. It is estimated that the three weeks the Ford 
 engineers took to solve the problem of cylinder 
 forgings represented a saving of nine months in 
 attaining maximum output of Liberty motors.
 
 120 Wings of War 
 
 From that time on the Fords made the cylinder 
 forgings for all the Liberty motor makers each of 
 them, of course, finishing the forgings in his own 
 plant. 
 
 It is easy to talk of profiteering and to say that 
 all who fought in the war with the forge and the 
 machine fought only for gain. There were many 
 greedy profiteers, but one of the fine experiences 
 of the war for those who were in the press of the 
 industrial preparation was the fact that patriotism 
 and the desire to serve at any cost were the domi- 
 nating motives with thousands of our manufac- 
 turers. In no effort was this better exemplified than 
 in the conception and production of the Liberty 
 motor. The spirit of sacrifice was shown when the 
 two engineers, Hall and Vincent, gave up their 
 pride of name and firm that an all- American motor 
 might be brought forth. Afterward it was shown in 
 every step of production. Every manufacturer of 
 the "Liberty" was of the mind of "Uncle" Henry 
 Leland, who chose aerial engine-making as his form 
 of service even before war was declared, and des- 
 pite his seventy-five years made a record of accom- 
 plishing greatly in a short time that might stir the 
 emulation of vigorous men of half his years. Like 
 the Packard Company, with Alvan Macauley 
 leading, all were willing at any time to suffer that
 
 Liberty Engine Production 121 
 
 the common cause might be well served. For the 
 time and the cause they ceased to be rivals and 
 brought together much of the best engineering 
 genius and productive talent in America to do 
 their part in giving to the Allied cause the greatest 
 of aerial motors. 
 
 While they pooled their strength and their skill 
 they did not shift responsibility from the individ- 
 ual group. Each company played its part of the 
 game with more energy and more perseverance 
 than it ever played its own private trade game. 
 It was a thankless game, too. At one time, when 
 the wind of public opinion sat strongly against the 
 Liberty engine, to be associated with it was to be 
 soiled with scandal. It was a service of dishonor 
 rather than honor. The cloud of misunderstand- 
 ings and fallacious judgments that resulted from 
 inevitable delays and the hullabaloo raised by 
 investigations, private and public, journalistic and 
 official, which promoted delay rather than prog- 
 ress, is already well cleared away. Time will do 
 full justice. Through it all the manufacturers, 
 like Colonel Deeds and his staff, never wavered in 
 their faith in their engine. In time to come they 
 will point to their loyal work on the great motor 
 as the noblest achievement of their careers.
 
 CHAPTER XIII 
 1 
 
 "DEVELOPMENT AND PRODUCTION OF ENGINES 
 OTHER THAN THE LIBERTY 
 
 BECAUSE the Liberty was the outstanding origi- 
 nal feature of the air program and the storm of 
 criticism and investigation so densely raged around 
 it, the public realized little of what was being done 
 in the way of studying, developing, and manufac- 
 turing other engines, both those required for the 
 rapidly expanding training service and to supple- 
 ment the Liberty as a service engine. 
 
 Some account has already been given of how 
 the Curtiss engine, the 0X5, was adopted as the 
 engine around which the training equipment was 
 built up, and how the Hall-Scott engine was used 
 in a supplementary way. Also there has been 
 some mention of the three foreign engines that 
 were put into production in this country primarily 
 as the power for secondary or 'advanced training. 
 
 It was the first intention after the adoption of 
 the Liberty motor idea to have the motor made in 
 4, 6, 8, and 12 cylinders, thus giving every degree 
 
 122
 
 Engines Other than the Liberty 123 
 
 of power that might be required for the different 
 uses all the way from training to the highest type 
 of single- and two-seater pursuit machines, obser- 
 vation, bombing, etc. 
 
 This symmetrical program, realizing as it did the 
 height of simplicity and standardization, was never 
 fully worked out. As a matter of fact the eight- 
 cylinder was the only variation from the standard 
 12 ordered in production. Both the four- and 
 six-cylinder sizes were built, tested, and proved but 
 had not been put in production on the signing of 
 the armistice. The first plan was to put a large 
 number of the 8's into production, even ahead of 
 the I2's. Then on advice from abroad, the ever- 
 repeated advice in favor of higher power, the 
 eight-cylinder was given up only to be returned 
 to during the closing days of the war. When the 
 necessity of having engines of intermediate power 
 became apparent with changing counsels and 
 changing circumstances, it was found an easier 
 matter, with the organization concentrated on the 
 Liberty I2's, to fill the gap with Hispano-Suizas. 
 So preparations were made with the Wright- 
 Martin Company which was then making the 150 
 H. P. Hispano-Suiza to take up the 22O-H. P. 
 model. Then reports came in from abroad that 
 on account of troubles arising from the gearing it
 
 124 Wings of War 
 
 should be discontinued. Another shift in the avia- 
 tion wind in 1918, making an engine of 300 H. P. 
 desirable at an early date for the smaller service 
 'planes, to the manufacture of which we were then 
 swinging back, resulted in an order for 10,000 of 
 the 3OO-H. P. Hispano-Suiza engines which had 
 just been developed abroad. As such an order was 
 quite beyond the capacity of the Wright-Martin 
 plant at New Brunswick, the government-owned 
 plant at Long Island City, formerly belonging to 
 the General Vehicle Company was leased to the 
 Wright-Martin Company to enable it to handle half 
 of the order. The other 5000 were placed with the 
 Pierce- Arrow Motor Car Company of Buffalo. To 
 assist both of these companies in their heavy task, 
 the entire manufacturing plant and facilities of the 
 H. H. Franklin Company of Syracuse, New York, 
 were placed at their disposal . These large Hispano- 
 Suizas would have gone into production in January, 
 1919, had not the end of the war intervened. 
 
 One of the most common criticisms of the man- 
 agement of aircraft production relates to the Rolls- 
 Royce, the excellent British motor. It is not gen- 
 erally known that it was originally the fixed inten- 
 tion, and a very persistent effort was made, to put 
 it into production in this country, notwithstanding 
 the great difficulties that were found to interfere
 
 Engines Other than the Liberty 125 
 
 with the naturalization of any foreign machine in 
 American factories. It is possible that had nego- 
 tiations not been so delayed and so productive of 
 problems the Rolls-Royce might have been the 
 high-power engine of the American program. It 
 was the one European engine of high power that 
 had been well developed when the United States 
 entered the war, though its power at that stage of 
 development was not great as compared to the 
 power later developed by the Liberty 12. To 
 those who did not appreciate the difficulties and 
 time required to put a foreign engine into success- 
 ful manufacture in the United States it always 
 seemed that one of the obvious things to do was to 
 produce the Rolls-Royce in the United States. 
 At one time there was a fixed intention to bring 
 about that consummation. Through Lord North- 
 cliffe, head of the British business mission in the 
 United States, arrangements were made for Mr. 
 Claude Johnson, managing director of the Rolls- 
 Royce Company, to come to the United States 
 with competent assistants, samples, drawings, 
 specifications, etc., in order to prepare for the man- 
 ufacture of his engine in this country. The first 
 plan was for Mr. Johnson to make an arrangement 
 with the Fierce-Arrow Motor Car Company for it 
 to undertake the building of the engine. This sug-
 
 i26 Wings of War 
 
 gestion was not well received by Mr. Johnson 
 because it meant turning over to a rival manufac- 
 turer, as it were, the inside knowledge and experi- 
 ence of his own business. After the war the 
 Fierce-Arrow Company might conceivably have 
 turned to its own advantage what it learned in 
 manufacturing the Rolls-Royce aero engine. Mr. 
 Johnson's idea was for the United States to acquire 
 and fully equip a factory and hand it over to him. 
 He stipulated that the factory must be located in a 
 good labor supply center and within a suitable dis- 
 tance, having in mind the transportation of raw 
 materials, from Pittsburgh. Then began the pur- 
 suit of the ideal factory. If the Signal Corps 
 approved of one, Mr. Johnson did not, and the 
 plants that were satisfactory to Mr. Johnson were 
 not liked by the Corps. Weeks of such negotia- 
 tion dragged into months. Meanwhile the Liberty 
 engine was designed, experimentally built, tested, 
 and approved; and by that time, in view of esti- 
 mated outputs, there seemed little reason for 
 taking up the Rolls-Royce. Another element in 
 the Rolls-Royce problem was the fact that Mr. 
 Johnson wished to produce at first his 190, devel- 
 oping 250 to 270 H. P., seemingly because he could 
 bring from England a complete set of jigs and 
 fixtures. With the aid of these he thought he
 
 Engines Other than the Liberty 127 
 
 could make 500 engines by the end of the fiscal 
 year; i. e., June 30, 1918. But the demand of the 
 times was for the Rolls-Royce 270 rather than the 
 190, and for it the jigs and fixtures would have to 
 be made in this country, thus lengthening the 
 schedule of deliveries. In the light of the record 
 made in the manufacture of Liberty motors the 
 final decision to drop the Rolls-Royce seems to 
 have been wise, as 1000 Liberties were actually 
 completed a month sooner than Mr. Johnson 
 figured on completing 500 of the smaller Rolls- 
 Royce. It is noteworthy, too, that the Liberty 12 
 weighed 100 pounds less and developed about 
 loo H. P. more than the larger Rolls-Royce. 
 It is now plain that if the Rolls-Royce had finally 
 been put into production in America the net result 
 would simply have been the output of a machine 
 whose place in the program would have been pre- 
 viously met by the Liberty Motor and that in 
 doing so the manufacturing resources of the coun- 
 try would have been overtaxed to such an extent 
 that neither the Liberty nor the Rolls-Royce would 
 have attained quantity production at anywhere 
 near the time the Liberty alone did. 
 
 The Boiling Commission was much impressed 
 with the Bugatti engine, which it found in the 
 developmental stage in France. It was a i6-cylin-
 
 128 Wings of War 
 
 der engine, weighing approximately noo pounds, 
 and was built around a small-caliber cannon. The 
 Boiling Commission strongly recommended that it 
 be put into production in the United States, and 
 that it be pushed side by side with and just as 
 energetically as the Liberty. The Duesenberg 
 Motor Corporation, of Elizabeth, N. J., was ac- 
 cordingly diverted from the Liberty and turned to 
 the Bugatti. The Fiat plant at Schenectady, 
 N. Y., and the Herschell-Spillman Company of 
 North Tonawanda, N. Y., were assigned to coop- 
 erate with the Duesenberg company. However, 
 when the sample engine arrived, it was found that 
 owing to an accident during a test in France it 
 was not in running order. Also, the French me- 
 chanics and engineers who came with it frankly 
 admitted that the design and development of the 
 engine had not been completed and that much work 
 remained to be done. Charles B. King, one of the 
 Signal Corps engineers, was assigned to this work. 
 It took months to re-design the engine and it was 
 just getting into production when the war ended. 
 Early in the war Mr. Harbeck of the Duesenberg 
 company suggested a plan of designing and build- 
 ing an engine of 800 H. P. The idea met with the 
 approval of the authorities and the Duesenberg 
 company was authorized to build four. One of
 
 Engines Other than the Liberty 129 
 
 them was completed before the armistice was 
 signed. The purpose of this experiment was to 
 keep the organization thinking in terms of larger 
 power all the time. The Liberty was years ahead 
 of any other engine, it appeared, but it was con- 
 sidered wise to be ready for further advances. 
 The boldness of this step is illustrated by the fact 
 that technical experts had just figured it out that 
 it was not practical to absorb 400 H. P. in one 
 high-speed propeller, though the Liberty was do- 
 ing it. Instead of accepting their conclusion they 
 were asked to prepare calculations for one that 
 would go with the 8oo-H. P. engine. 
 
 The contracts for and deliveries of other engines 
 than the Liberty up to November 29, 1918, are 
 as follows: 
 
 CONTRACT 
 
 TYPE NUMBER DELIVERED 
 
 OXs 9,450 8,458 
 
 A?-A 2,250 2,250 
 
 Gnome 342 240 
 
 Le Rhone 3,900 1,298 
 
 Lawrence 451 451 
 
 Hispano-Suiza 
 
 180 H. P 4,500 
 
 150 H. P 4,000 4,100 
 
 300 H. P 10,000 
 
 Bugatti 2,000 1 1 
 
 Total 36,893 16,848
 
 130 Wings of War 
 
 Including the Liberty motors (64,100) the orders 
 for engines at the time of signing the armistice 
 amounted to 100,995 which were to 'have been 
 completed by January i, 1920, or thirteen months 
 after the cessation of hostilities. There were deliv- 
 ered 32,420 with a total horsepower of more than 
 7,800,000. Deliveries were somewhat further in- 
 creased in some items before production termi- 
 nated, the final total for Hispano's, for example, 
 being 6176. 
 
 The distribution of engines completed up to 
 November 29, 1918, was as follows: Of the train- 
 ing engines 325 Le Rhone rotaries went to the 
 A. E. F., the various airplane factories received 
 9069 of different kinds, 6376 of them were sent to 
 the training fields, and 515 Hispano-Suizas went to 
 the navy ; of the combat engines, mostly Liberties 
 but including some of the higher-power Hispano- 
 Suizas, 3746 were delivered to the navy, 1090 were 
 taken by the Allies, 941 were sent to training 
 fields, and 5327 were sent to 'plane plants for instal- 
 lation in airplanes. 
 
 It is true that this engine-making achievement, 
 great as it is, is not up to the promise of the rosy 
 early days. In general the full realization of the 
 early program, taking engines and 'planes to- 
 gether, would have come in about twenty months,
 
 Engines Other than the Liberty 
 
 instead of the hoped-for twelve months, from 
 July I, 1917. Yet, as John D. Ryan recently 
 pointed out, we did well in comparison with our 
 allies or our enemies. "We built more 'planes," 
 he said, "month for month, from the time we 
 began than any other nation in the war built from 
 the time it began. We had more engines ready 
 and we had more 'planes ready, month by month, 
 from the time we commenced than any nation in 
 the war had from the time it commenced." The 
 same fact may be stated in another way by saying 
 that in each corresponding period of time in our 
 participation in the war we produced aircraft in 
 greater volume than any other nation in it.
 
 CHAPTER XIV 
 
 CENTRALIZATION OF MANUFACTURING 
 RESPONSIBILITY 
 
 ONE of the fixed ideas of the early nebulous 
 stage of the American aircraft program was that 
 of brevity in respect to the list of machines that 
 should be manufactured. There were to be but 
 few types of engines and 'planes and the engines 
 were to be as far as possible modifications of a 
 standard type. 
 
 This was exactly the reverse of the French and 
 British method of procedure. With them each 
 manufacturer was allowed to go ahead almost 
 independently with his own conceptions. It has 
 been asserted that while the American method had 
 its advantages, it also had the disadvantage that 
 it tended to check development and invention and 
 practically relegated them to the official organi- 
 zations. Doubtless this was true in a degree, but 
 one of the offsets was that in some measure all of 
 the available engineering talent of the country was 
 
 132
 
 Manufacturing Responsibility 133 
 
 united and concentrated on the lines the aircraft 
 organizers sought to lay down. If there had been 
 more aeronautical engineering ability in this coun- 
 try at the beginning of the war it might not have 
 been necessary to concentrate it to so great a 
 degree as it was along the lines laid down by the 
 government. 
 
 Both the aeronautical engineers and the existing 
 aircraft plants had to be carefully conserved. Far 
 from being ignored, they were zealously cultivated, 
 though not always in the ways they preferred. 
 Doubtless some of the small plants, simply because 
 they were called aircraft plants, thought that even 
 the Liberty motor should have been entrusted to 
 them, rather than to the highly organized and 
 amply equipped automobile manufacturers the 
 great internal combustion engine designers and 
 builders of America. 
 
 The automobile manufacturers besides being 
 most proficient in the designing and making of 
 internal combustion engines had the decisive ad- 
 vantage of organizations and plants that lead the 
 world in the excellence and capacity of their quan- 
 tity production methods. One of the most irra- 
 tional criticisms of the aircraft managers that was 
 made in the hectic early days of the war was that 
 they had entrusted the building of aerial motors
 
 134 Wings of War 
 
 to the manufacturers of automobile motors. The 
 authors of this criticism did not point out what 
 American industry, in the absence of an extensive 
 and highly specialized aerial motor industry, 
 should build aeroplane motors if not the makers of 
 automobile motors. In France, England, Italy, 
 Germany everywhere the automobile manufac- 
 turers have inevitably evolved into producers of 
 aircraft. The conversion of a number of the superb 
 automobile-making plants of the country to the 
 making of Liberty and other motors and of 'planes 
 was one of the notably logical industrial mobili- 
 zations of the war. 
 
 The aeronautical engineers .were utilized, as a 
 rule, not by bringing them to Washington or to 
 the engineering headquarters at Dayton, but in 
 conjunction with their own existing plants or some 
 that were later built up around them. The exist- 
 ing plants that amounted to anything were divided, 
 in the first place, between the army and navy. 
 In magnitude the army aviation effort was so much 
 in excess of the navy's that it may have been over- 
 looked that the Aircraft Board had always to make 
 equitable provision for the latter. 
 
 To the navy were assigned exclusively the 
 Burgess factory at Marblehead, the Aeromarine 
 plants at Nutley and Keyport, N. J., and the
 
 Manufacturing Responsibility 135 
 
 Boeing plant at Seattle. The enlarged Curtiss 
 plants were used for both army and navy work 
 and the Standard Aircraft Corporations' plant at 
 Elizabeth, N. J.; the Thomas-Morse Aircraft Cor- 
 poration, Ithaca, N. Y.; the Wright-Martin Air- 
 craft Corporation, Los Angeles, and the Sturtevant 
 Aeroplane Company of Boston were turned over 
 to the army. 
 
 The engineering tasks were roughly assigned in 
 the following manner : To Glenn Curtiss and the 
 engineering staff of the Curtiss company the 
 JN-4-D and the development of the drawings and 
 the manufacture of the French Spad the single- 
 seat chasse machine which was early adopted as 
 the type of single-seater fighter that would be put 
 into production in this country. Later the Curtiss 
 company got the unfortunate Bristol two-seater 
 fighter and finally the U. S. E>9-A, that was 
 intended to take the place of the Bristol. 
 
 A new company, the Dayton- Wright Airplane 
 Company, was encouraged to build up around the 
 nucleus of Orville Wright and engineers and 
 trained mechanics associated with him, and to it 
 was assigned the development and pioneering of 
 the De Haviland 4 with the Liberty motor as 
 power. 
 
 Originally the Signal Corps Engineering Depart-
 
 136 Wings of War 
 
 ment was assigned to the Bristol but the latter 
 part of that development was transferred to the 
 Curtiss company. 
 
 The Thomas-Morse corporation, with B. D. 
 Thomas at the head of its engineering, was assigned 
 to the development of a rotary motor advance 
 training 'plane, and later, a chasse machine. 
 
 Grover C. Loening was instructed to develop a 
 two-place fighter. 
 
 Glenn L. Martin was told to develop a two- 
 engine bomber. 
 
 Lewis & Vought were told to develop an advance 
 training 'plane under the guidance of C. M. Vought. 
 
 Several orders for experimental machines were 
 also placed. 
 
 This seemed like a rational and simple arrange- 
 ment, but the admitted fact is that engineering 
 confusion ensued in 'plane manufacture. "The 
 engineering confusion which followed the program 
 throughout the first year," says an official state- 
 ment, "must be frankly admitted." It somehow 
 seemed impossible to introduce into the engineering 
 of the 'planes the orderly method that governed the 
 development of the Liberty motor. That was partly 
 due to the fact that it was an American design and 
 did not wait upon foreign counsel ; it was also due 
 to the fact that an engine was a complete unit in
 
 A Curtiss Training Plane at Kelly Field 
 
 U. S. Air Service Photo 
 
 Elmwood Plant of the Curtiss Aeroplane and Motor Corporation, Buffalo, New 
 
 York, Erected Exclusively for War Airplane Work, and 
 
 Employed 15,000 Persons
 
 Manufacturing Responsibility 137 
 
 itself and did not have to be considered with 
 respect to numerous accessories. But above all 
 there were highly organized industrial facilities for 
 engine production which did not exist for 'planes. 
 In the case of the 'planes there was also the diffi- 
 culty of a lack of definite knowledge of just what 
 was required and the further complication of deter- 
 mining upon and designing the accessories, as 
 well as providing for their manufacture from the 
 ground up in many instances, at the same time 
 that the 'planes were being designed. A place 
 for each of the accessories had to be found, but it 
 was never certain just how many kinds of them 
 there would be, because of our varying demands 
 from the front. On the other hand the accessories 
 had to be adapted to the limitations of space 
 in the cockpit, in the engine compartment or the 
 landing gear, or on the outside of the fuselage. 
 Doubtless, at some point someone should have 
 been able to step in and say that a certain num- 
 ber of machines should have such and such an 
 equipment, leaving additions and improvements 
 to a following series. But the early general air 
 service organization seemed to make this impos- 
 sible. The engineers felt constrained to look upon 
 a request from the A. E. F. as an order so, 
 much time was wasted in trying to overtake an
 
 138 Wings of War 
 
 objective that moved forward as rapidly as it was 
 approached. Whether there was in America at 
 the time we entered the war any potentiality of 
 an organization that could have avoided confusion 
 is doubtful. Order in procedure is primarily based 
 on a clear conception of what is to be done and 
 on the existence of a supreme authority that can 
 steadily direct progress toward the objective. It 
 is noteworthy that even in England where the 
 aircraft organization was further advanced at the 
 time England entered the war than it was with us 
 when we went in, a similar confusion prevailed for 
 over two years. 
 
 The general policy of simplicity also governed 
 the choice of manufacturers. There were thou- 
 sands of applicants for contracts and from one 
 point of view it seemed that the thing to do was to 
 start everybody who offered on some sort of air- 
 craft production. This policy was not followed 
 because Colonel Deeds understood that American 
 manufacture was of the quantity kind and could 
 not adapt itself to a multiplicity of participants as 
 the group manufacturing methods of Europe did. 
 Hundreds of the applicants were, however, pains- 
 takingly investigated but the majority of them 
 were found hopelessly unfit for the task. Many of 
 them felt that they had a grievance and it was
 
 Manufacturing Responsibility 139 
 
 therefore, easy for their sympathizers to complain 
 that but a small percentage of the potential air- 
 craft production of the country was being utilized, 
 whereas the real difficulty was to make effective 
 use of the facilities of the plants that were enlisted. 
 One of the aspirants for 'plane manufacture was a 
 stone quarry company and there were many others 
 almost as impossible. As a rule, original contracts 
 were put into a few responsible hands. The 
 holders of these contracts then contracted second- 
 arily for those parts they did not make in their 
 own plants as well as for materials. In the end 
 over three hundred plants and more than two 
 hundred thousand work-people were engaged in 
 the making of 'planes and accessories. 
 
 As the delays in production were chiefly due to 
 engineering confusion, it is now easy to see that 
 the situation would have been indescribably cha- 
 otic if the plants affected had been much more 
 numerous than they were. They had ample capac- 
 ity but the engineering jam held them back. The 
 same policy of concentration in the hands of the 
 strong gave us engines in abundance before it gave 
 us 'planes. 
 
 In considering this subject it is necessary to bear 
 in mind that in the automobile industry we had in 
 America a great body of trained builders of internal
 
 140 Wings of War 
 
 combustion engines of which, after all, an aero motor 
 is only a specially refined and adapted type. The 
 builders of the 'planes were generally without cor- 
 responding experience and their work-people were 
 without training, and yet it was their task to fit 
 the new engines to the 'planes and also properly 
 place in them numerous sorts of equipment appa- 
 ratus which never ceased to grow in number and 
 complexity. Thus, in a way, it may be said that 
 most of the elemental difficulties of producing fin- 
 ished combat aeroplanes piled up in the aeroplane 
 factories where the 'planes proper, the motors, and 
 the accessories were assembled into the function- 
 ing whole. In the same manner they had to bear 
 the brunt of the delays and alterations of all kinds 
 that affected motors and other equipment. That 
 this point is well taken is supported by the com- 
 parative ease and rapidity with which the manufac- 
 turers of training 'planes attained volume produc- 
 tion. The latter merely had to build or build and 
 assemble simple 'planes and engines and had little 
 or no engineering or pioneering developmental 
 work to do. They merely traveled along a sepa- 
 rate and well-beaten path. Their brethren of the 
 combat 'planes, however, had all of the problems 
 of the adaptation of foreign 'planes and then had 
 to wait on the solutions by their predecessors in
 
 Manufacturing Responsibility 
 
 the line of production of all their problems of origi- 
 nation and adaptation. 
 
 Another step toward simplification that was 
 early taken was the matter of patents and royal- 
 ties. It was clear that if American manufacturers 
 were to pool their efforts for the common good 
 some equitable arrangement for common access 
 to all existing rights must be obtained. Permission 
 to use these rights could not be left to the disorder 
 of individual bargaining, with its delays, disap- 
 pointments, and general tendency to result in 
 excessive cost. Howard E. Coffin and S. D. 
 Waldon took the initiative in this matter several 
 months before war was declared and succeeded 
 in getting an Aircraft Manufacturers' Association 
 formed around a so-called cross-licensing agree- 
 ment that was at one time the cause of much criti- 
 cism. It is important to note that the initiative 
 came from the government, and that the motive 
 was most laudable the purpose being to serve the 
 common cause in an equitable manner without 
 doing injustice to the pioneers of the industry who 
 held the basic patents as well as desirable designs 
 and processes of manufacture. All members of the 
 association and membership was open to any 
 legitimate manufacturer had the privilege of 
 using the basic patents on the payment of a cer-
 
 i4 2 Wings of War 
 
 tain sum for each commercial machine turned out 
 and half as much for each government machine. 
 The solution of the inter-relations of manufac- 
 turers thus arrived at eliminated all patent litiga- 
 tion which at one time was threatening untoward 
 complications and gave just recognition of the 
 pioneering work that was so necessary to the suc- 
 cess of the aircraft program. 
 
 The rights to European designs of engines and 
 'planes were dealt with through the Allied govern- 
 ments. Enterprising Americans as well as for- 
 eigners saw a chance to make an honest penny or 
 mayhap a million or two by acquiring the Amer- 
 ican rights of foreign 'planes and engines. Many 
 of the machines thus covered did not interest the 
 American producers but among them were the 
 "Clerget" engine, recommended by the Joint 
 Army and Navy Technical Board for use in train- 
 ing 'planes ; the Sopwith, also favorably considered ; 
 the "Sunbeam," not favorably considered, and 
 such desired rights as those of the Caproni, Gnome, 
 Le Rhone, and Handley-Page. The valuation 
 placed on these rights made the figures of the cross- 
 licensing agreements with American manufac- 
 turers look absurdly small. As the election of 
 foreign types was left to the Boiling Commission 
 this matter of royalties was also left to it and it
 
 Manufacturing Responsibility 143 
 
 settled it on the sensible basis of free interchange 
 of rights between governments, leaving each 
 government to deal with the rights of its own 
 designers. The two exceptions to this practice 
 were the negotiations with the Rolls-Royce com- 
 pany and the three French engines and 'planes 
 that were selected through Major Tulasne of the 
 French military mission at Washington.
 
 CHAPTER XV 
 
 THE WRESTLE WITH THE 'PLANES 
 
 THE uncertainty as to what to undertake in this 
 country in the way of service 'planes resolved it- 
 self in August, 1917, on instructions from abroad, 
 into a general determination to adopt the De 
 Haviland 4 as the type for reconnaissance, with 
 secondary functions as a day-bomber and a defen- 
 sive bi-place fighter. The Bristol two-seater was 
 adopted as the type for the two-seater fighter and 
 the Spad as the single-seater chasse machine. By 
 that time, too, the Boiling Commission was begin- 
 ning to get a very clear view of the engine situation 
 and had cut its immediate production recommen- 
 dations down to only the Rolls-Royce, the Gnome, 
 and the Le Rhone of foreign engines. 
 
 The De Haviland 4 was the first foreign service 
 'plane to reach this country. It was a seven days' 
 wonder in Washington, where it arrived in the lat- 
 ter part of July, even though it came without 
 engine, ordnance, and the operating equipment. 
 
 144
 
 w 
 
 Q 
 
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 a 
 
 bo 
 
 .9 
 
 i
 
 The Wrestle with the 'Planes 145 
 
 Incomplete as it was, it was the first service 'plane 
 to reach America. It had to be redesigned to take 
 the Liberty engine and altered to suit the Marlin 
 and Lewis machine guns, four in all, and finally 
 shaped and stretched to hold a host of accessories, 
 the number of which, it seemed to the despairing 
 engineers, never ceased to grow. 
 
 The aircraft managers then got their first 
 glimpse of the troubles that were ahead of them. 
 Accustomed to American practice, they had con- 
 sidered that with regard to the foreign machines, 
 engineering would be the least of their difficulties. 
 The naked De Haviland 4 and the incomplete 
 drawings that followed it opened their eyes. This 
 sample arrived at Dayton, Ohio, on August 18, 
 1917, and was turned over to the Dayton-Wright 
 Airplane Company for study and reproduction. 
 The first American-made DH-4, without equip- 
 ment, took the air with a 12-cylinder Liberty 
 motor October 29th. It gave perfect satisfaction 
 from the first; and patched up from time to time, 
 with the tireless Howard M. Rinehart as operator, 
 this veteran "Canary, " as it came to be known on 
 account of its color, was the operating subject 
 through all the long struggle that followed to get 
 more things into the 'plane than there was room 
 for. The fact that the first 'plane was ready so
 
 146 Wings of War 
 
 soon even though it was not a machine-made 
 one and the other fact that quantity production 
 from a well-organized and ably directed plant was 
 not in full swing until the following April tells the 
 tale of the accessories. But for them and their 
 baffling problems of design, location, and manu- 
 facture the 'planes should have been coming out 
 in quantities much faster than the engines, whereas 
 in fact, it was the other way about. It is hopeless 
 to convey any idea of the exasperating nature of 
 the complications with respect to them. The task 
 would have been simple, indeed, had it been merely 
 the matter of duplicating a foreign machine with 
 each accessory in its place, complete drawings, and 
 the accessories available. The latter were the cur- 
 rent by-product of aerial warfare. Mostly, they 
 were entirely new to America all the way from 
 suitable photographic apparatus to machine gun 
 synchronizers. Besides, each morning's cable- 
 grams brought some more recommendations either 
 for additional accessories or variations of those 
 already adopted. And always there was a warning 
 that 'planes without these up-to-the-minute de- 
 vices would be antiquated before they reached 
 Europe. During these intense and critical days 
 the storm of criticism and investigation was at 
 its height and reorganizations were adding to the
 
 General Arrangement of Throttle and Gas Control, and Other 
 
 Instruments in Pilot's Cockpit of a DH-4. The Numerous 
 
 Installations in a Limited Space were a Hard Problem 
 
 for the Designers 
 
 U. S. Air Service Photo
 
 The Wrestle with the 'Planes 147 
 
 burdens of the aircraft managers; all of which 
 took up the time and diverted the energies of those 
 in charge to the point of discouragement and de- 
 moralization. By this time also army organiza- 
 tion was beginning to get its grip on the civilian 
 method of doing business and was crushing it into 
 the rigid and angular process of government rou- 
 tine plus military stiffness. The De Haviland 4 
 had, too, all the familiar troubles of inaccurate, 
 partial, and incomplete foreign drawings. Manu- 
 facturing drawings, in the American sense of com- 
 pleteness and detail, do not seem to exist in 
 Europe. At least that was the conclusion our air- 
 craft manufacturers arrived at. The fact is that 
 the European system of individual work and a 
 small measure of standardization do not require it. 
 If this difference in practice had been understood 
 sooner, there would not have been so much confi- 
 dence as to early 'plane production. The actual 
 manufacture of 'planes was not considered as diffi- 
 cult as that of engines. The motor is a complex 
 power producing machine, with hundreds of mov- 
 ing parts, whereas the 'plane for all its forty thou- 
 sand parts is a rigid structure; and it was believed 
 that in view of the fact that the body was largely 
 of wood and cloth and the metallic parts easily 
 adapted to machine production it would not be
 
 148 Wings of War 
 
 difficult. Incomplete and unsatisfactory draw- 
 ings, which necessitated the making of thousands 
 of new drawings from the model, the problem of 
 placing the ever-accumulating and ever-changing 
 accessories and changes incidental to adaptation to 
 the Liberty motor dispelled the dream of an easy 
 job. So, in the end the naturalized foreign 'planes 
 came through more slowly than the home-born 
 Liberty motor. This fact suggests the possibility 
 that a naturalized foreign motor might have been 
 relatively much longer in reaching production. 
 
 The De Haviland 4 was officially released for 
 production in April and the Dayton-Wright Com- 
 pany thereafter lived up to its manufacturing 
 schedule. In June it was turning out fifteen com- 
 plete machines a day guns, accessories, and all 
 and in August completed its thousandth machine 
 on time. When the armistice was signed it had 
 realized the unprecedented rate of forty complete 
 'planes a day. More than two thousand 'planes of 
 its make were in or on the way to France when hos- 
 tilities ceased. The Fisher Body Company, Detroit, 
 had attained an output of thirty -five De Havilands 
 daily. When De Haviland 4 production ceased in 
 December there had been turned out by all makers 
 4587 machines, practically all in eight months. 
 
 The first DH-4's had their faults and imperfec-
 
 The Wrestle with the 'Planes 149 
 
 tions and the experience of actual military use 
 resulted in alterations and improvements by the 
 aviation shops in France and like changes in the 
 manufacturing plants at home, but this did not 
 interfere with production and was all part of the 
 interminable game of keeping up with the daily 
 lessons of experience at the front. 
 
 Maj. A. A. Cunningham, commandant of the 
 Aviation Section of the U. S. Marine Corps, in 
 telling of the excellences as well as the defects of 
 the American DH-4's, as used by the marines in 
 cooperation with the British service, says that 
 they were so much faster than the British DH-4*s 
 equipped with the BHP motor that they found it 
 very difficult to stay in formation with the latter. 
 This difficulty was overcome by throttling down 
 the Liberty motor and carrying only about one 
 half the regular weight of bombs. Even in flying 
 with the 'planes using Rolls-Royce Eagle-8 motors, 
 it was found desirable for the latter to carry a 
 smaller weight of bombs. "On account of the ex- 
 cellent performance of speed of the American Lib- 
 erty motored 'planes," he says, "the British were 
 well pleased with them. When the first few re- 
 ceived were recalled, in order to start independent 
 (American) operations, one squadron commander 
 wrote an enthusiastic report regarding the per-
 
 Wings of War 
 
 formance of these 'planes while in use with his 
 squadron." 
 
 "In my opinion," continues Major Cunningham, 
 "the Liberty DH-4 and DH-Q-A were the fastest 
 and climbed better, at above fifteen thousand feet, 
 than any plane, Allied or German, on the front, 
 As an illustration, the Hun biplane and triplane 
 Fokker scouts had been accustomed to meeting the 
 British DH's and could outclimb and outspeed 
 them. On our first independent raid, the forma- 
 tion was attacked by about twice their number of 
 Fokker s. We promptly shot down two of them 
 and then climbed away from the remainder as if 
 they had been tied down. The actions of the Huns 
 plainly showed their amazement. This was their 
 first experience with the Liberty motor." 
 
 As a step in advance the U. S. DH-Q-A was 
 designed soon after the De Haviland 4 got into 
 production and four thousand of them were 
 ordered from the Curtiss company after the Bristol 
 two-seater was abandoned. While most of the De 
 Haviland 4*5 were made by the Dayton-Wright 
 Company, the Standard Aircraft Corporation and 
 the Fisher Body Company (Detroit) had got into 
 production before the war ended. 
 
 The characteristics of the De Haviland are as 
 follows :
 
 Making Airplane Wings 
 
 
 Bird's-Eye View of the Dayton- Wright Airplane Company's Plant at Moraine, 
 
 near Dayton, Ohio
 
 The Wrestle with the 'Planes 
 
 Endurance at 6500 feet, full throttle. 2 hrs., 13 min. 
 Endurance at 6500 feet, half throttle.3 hrs., 3 min. 
 Ceiling .......................... 19,500 feet 
 
 Climb to 10,000 feet (loaded) ...... 14 min. 
 
 Speed at ground level ............. 124.7 mi. per hr. 
 
 Speed at 10,000 feet .............. 120 mi. per hr. 
 
 Speed at 15,000 feet .............. 113 mi. per hr. 
 
 Weight, bare 'plane ............... 2391 pounds 
 
 Weight, loaded ................... 3582 pounds 
 
 The production of De Haviland 4 machines is 
 as follows : 
 
 November, 1917 ........................... 
 
 December ................................. 
 
 January, 1918 ............................. 
 
 February ................................. 
 
 March .................................... 4 
 
 April ..................................... 15 
 
 May ..................................... 153 
 
 June ..................................... 336 
 
 July ...................................... 484 
 
 August ................................... 234 
 
 September ................................ 757 
 
 October ................................... 1,097 
 
 November ................................ i ,072 
 
 December ................................. 456 
 
 Total 4,587 
 
 The De Haviland 4*5 were the only American- 
 made service machines delivered to the A. E. F. 
 The decision made on recommendation from
 
 i5 2 Wings of War 
 
 General Pershing and the Boiling Commission in 
 1917 to leave the pursuit machines to European 
 makers was reversed too late for us to be repre- 
 sented by them, and the failure of the attempt to 
 adapt the Bristol two-seater resulted in lack of 
 representation in two-seater fighters. However, 
 there was a great need for the reconnaissance 
 machines when they did arrive and after all the 
 main military value of airplanes was reconnaissance. 
 The fighters' raison d'etre was chiefly to protect 
 and assist them and though the De Haviland 4*5 
 were technically classed as observation and bomb- 
 ing 'planes, they were able on account of their 
 speed, the rapidity of their ascent, the height of 
 their ceiling, and the nature of their armament, to 
 give a very good account of themselves in a fight. 
 By the time they began to arrive in France in num- 
 bers, the foreign deliveries of fighters had much 
 improved, and when the armistice was signed our 
 forces abroad had received more than five thousand 
 'planes, service and training, from foreign makers 
 mostly French and 3302 were in use. 
 
 To be sure, one feels a sort of diffidence about 
 saying much about the French contribution to our 
 aerial fighting equipment for no matter how suf- 
 ficient the explanations it is not pleasant to have 
 to admit that so great an industrial country as
 
 The Wrestle with the 'Planes 153 
 
 ours had to lean so heavily on French industry. 
 It was so and inevitably so in order that American 
 man power might make itself felt decisively in the 
 battle front of 1918. 
 
 The Allies understood the situation, and when 
 Boiling left for Europe in June, 1917, he carried 
 with him the firm conviction, upon which all his 
 later conclusions were based, that America with no 
 engine or 'plane industries and without engine and 
 'plane designs suitable for war service, could not 
 be ready to begin making shipments to France 
 under twelve to fifteen months whether we copied 
 or originated. Boiling knew even then that the 
 Allies must not only hold the battle line, but must 
 help us in training and in equipment until we could 
 overcome the tremendous lead in the new science 
 and art of aerial combat, which had been gained 
 by the great European powers while American 
 aviation slumbered. Boiling fully presented the 
 deplorable status to General Pershing and recom- 
 mended that all aviation equipment needed in 
 France, before July, 1918, be bought from the 
 English, French, and Italians. Accordingly, orders 
 were placed in France and Italy, as described else- 
 where, for the machines that were to stop the gap 
 until the American "ships" should arrive, just as 
 French artillery, tanks, etc., had to be provided
 
 154 Wings of War 
 
 for about all the American combat units of 1917 
 and 1918. 
 
 Very likely aircraft and artillery matters might 
 have been handled better but the real mishandling 
 was before the war. The responsibility rests with 
 leaders and people who permitted the now incon- 
 ceivable folly of letting the horrific war in Europe 
 drag through well-nigh three years with no prepa- 
 ration worthy of the name on this side. To deal 
 harshly with the self-sacrificing men who did so 
 well to correct the fundamental blunder when it 
 was too late is merely to divert attention from the 
 cause to the effect. 
 
 Looking backwards, it is now plain that the 
 United States should not have withdrawn its 
 efforts to produce a single-seater fighting 'plane, 
 as it did when the Spad order was canceled in 
 December, 1917. Inconsequence of that decision 
 we should have been very short of a much needed 
 type in 1919, as we were in 1918. It was taken, 
 however, on the practically unanimous opinion of 
 General Pershing, our aviation representatives 
 abroad, and the Allied government authorities. 
 This subject has been touched upon heretofore, 
 but it is worthy of further elucidation, because 
 none of the critical investigations of aircraft pro- 
 duction have given it proper weight. They have
 
 The Wrestle with the ' Planes 155 
 
 been content to state the bare fact without the 
 circumstances, and leave the inference that it was 
 another fault of the equipment division of the 
 Signal Corps. The Spad sample reached the Cur- 
 tiss works in Buffalo on September 27th and it 
 was ordered into production on a large scale, only 
 to be revoked in accordance with instructions from 
 abroad, because it was the best judgment there 
 that the day of the single-seater was about over. 
 The attempt to Americanize the Bristol two- 
 seater fighter was the big, flat failure of American 
 aeronautical engineering. There is no doubt that 
 the selection of the Bristol was a wise one. The 
 failure was in adaptation. It is the common im- 
 pression that the failure was primarily due to the 
 fact that the Liberty motor and the Bristol were 
 incompatible, because of the much greater power 
 of the former than the Rolls-Royce engine that had 
 been used in it in the British service. Engineers 
 now state there was no such essential incompati- 
 bility, and point to the successful designing of 
 other two-seaters around the Liberty 12. The 
 redesigning of the Bristol was first taken up by 
 the Signal Corps aeronautical engineering staff, 
 working from a sample that reached Washington, 
 September 5, 1917, and from the original drawings. 
 When the Spad contract with the Curtiss Company
 
 Wings of War 
 
 was canceled the work was turned over to that 
 company with the government engineers cooper- 
 ating; next the engineering responsibility was 
 entirely shifted to the company; finally it was 
 sought to complete the work under the direction 
 of government engineers. The basic trouble, 
 which so much engineering shifting did not help, 
 was the fact that in attempting to put onto the 
 Bristol all the equipment of the De Haviland 4, 
 some eight hundred pounds of weight were added 
 without a corresponding extension of wing surface. 
 The machine was overloaded. Notwithstanding 
 this elemental error, so much time was taken up 
 with the baffling problems of redesigning to ac- 
 commodate equipment, that even sample machines 
 were not ready until well along in the spring of 
 1918. Their performance was unsatisfactory and 
 productive of casualties, and when John D. Ryan, 
 then at the head of the air division of the army, 
 witnessed the death of two aviators in an experi- 
 mental flight at Buffalo, he ordered the Bristol 
 experiment stopped. 
 
 This failure, while it was a costly one in respect 
 to waste of time and material, was not a disastrous 
 one, for the reason that the De Haviland 4, though 
 designated as an observation machine, and the Bris- 
 tol two-place fighter were in fact essentially the
 
 The Wrestle with the 'Planes 157 
 
 same type. Had the Bristol experiment succeeded it 
 would have gotten a very considerably larger num- 
 ber of machines in France before the end of the war, 
 but it would not have given any pronounced variety 
 to our aerial equipment there. The great restric- 
 tion of American aeroplane force in France was 
 due to the abandonment of the single-seater, the 
 Spad, in 1917. This was not a production fault, 
 being rather an error of military judgment, made, 
 as it now develops, against the conviction of 
 Colonel Deeds and his associates. Their prompt- 
 ing was to go ahead with the single-seaters, but 
 the decision did not rest with them. 
 
 While the Bristol experiment was approaching 
 its dismal end, Captain Lepere, a French aero- 
 nautical engineer originally brought to this country 
 for the purpose of designing a two-seater fighter 
 around the Bugatti engine, was achieving a bril- 
 liant success with such a 'plane built around the 
 Liberty motor. His work was done at the Packard 
 plant, a contract having been made with the 
 Packard Company to provide him with the shop 
 facilities to build 25 experimental 'planes. The 
 Lepere 'plane attained a speed of 136 miles an 
 hour at low levels and of 102 at 20,000 feet, to 
 which height it climbed in 41 minutes. Even at 
 10,000 feet its speed was 127 miles an hour, as
 
 158 Wings of War 
 
 compared with the Liberty De Haviland's 117. 
 Four thousand of these machines were ordered, but 
 there was no production before the armistice was 
 signed. It was confidently believed, however, that 
 in the Lepre the American air forces at the front 
 would have had the supreme two-seater fighter in 
 the spring of 1919. The Lepere represented the 
 union of the training and technique of the best 
 engineers of France with the Liberty motor, admit- 
 tedly the best of all aviation engines. Captain 
 Lepere also designed two other two-place fighters, 
 as mentioned below. 
 
 Just as 1917 saw the Liberty motor developed 
 and 1918 saw it in vast production, so 1918 saw 
 the development of 'planes in America and 1919 
 would have seen both American engines and fight- 
 ing 'planes produced in unequaled quantities and 
 in action at the front by the thousands. The 
 other experimental orders, all but three of which 
 have been delivered, and most of which are very 
 promising, are as follows: 
 
 SINGLE-SEATER PURSUIT 
 
 Thomas-Morse MB-3 3OO-H. P. Hispano engines 
 Vought VE-8 one-place fighter 3OO-H. P. Hispano 
 
 engines 
 Ordnance Engineering Model D 3OO-H. P. Hispano 
 
 engines
 
 A Loening Monoplane on the Ground 
 
 U. S. Air Service Photo 
 
 Loening Monoplane in Flight in the Clouds
 
 The Wrestle with the 'Planes 159 
 
 Pomilio Liberty 8 engine 
 Pomilio Liberty 12 engine 
 Verville 300 H. P. Hispano engines 
 
 TWO-SEATER FIGHTER 
 
 Lusac ii Liberty 12 engines 
 
 Lepere (armored) C-2I Bugatti engine 
 
 Lepre Triplane (day bomber) two Liberty 12 
 
 engines 
 
 Curtiss Triplane Kirkham engine 
 Curtiss Ground Harassment Biplane Bugatti engine 
 Loening 2-place Monoplane Liberty 12 engine 
 Loening 3OO-H. P. Hispano engine 
 USDgA and B Liberty 12 
 USXB-i 300-H. P. Hispano 
 USXB-2 Liberty 8 
 
 Thomas-Morse MB i and 2 Liberty 12 engine, 
 geared Martin Bomber (day bomber) two Liberty 
 
 engines 
 
 The Thomas-Morse Company, it should be 
 remarked here, also produced a scout machine 
 that was primarily intended for advanced training. 
 In the beginning it was the intention to complete 
 advanced training of aviators in Europe, and 
 great preparations were made at Issoudun, in 
 France, and elsewhere, for that purpose. Later 
 it was decided to complete the training of at least 
 part of the flyers in this country. The Bristol 
 Scout was recommended as the suitable machine 
 for this purpose. When the sample was received
 
 160 Wings of War 
 
 in this country it was turned over to the Thomas- 
 Morse people for adjustment and adaptation. It 
 was the general plan then to have this company 
 develop into the manufacture of single-place 
 fighters using the rotary engines. A sample 
 Nieuport was also provided for them as an object 
 of study and source of suggestions. Ultimately 
 the army aviation authorities reported adversely 
 on the Bristol Scout design and it was abandoned. 
 The Thomas-Morse Company then continued the 
 development of a one-place machine, of its own 
 design, using the Gnome engine at first and 
 the 8o-H. P. Le Rhone later, and this machine 
 has since become one of the regular training 
 machines. 
 
 The Morse MB-3, mentioned above, designed 
 to take the 3OO-H. P. Hispano-Suiza engine, is a 
 very promising machine. 
 
 Chas. M. Vought, besides designing the VE-8 
 single-seater pursuit machine, to use also the 300- 
 H. P. Hispano engine, was first instructed to build 
 a two-place advance training machine around the 
 I5O-H. P. Hispano. This machine had been ap- 
 proved and put into production at the plant of the 
 Springfield Aircraft Corporation. Production was 
 just beginning when the armistice was signed. It 
 gave promise of great excellence, and was pro-
 
 The Wrestle with the 'Planes 161 
 
 nounced by veteran fliers as the best of all two- 
 place training machines, foreign or American. 
 
 The Pomilio machines were the fruit of the 
 effort to have Italian designers build models 
 around the Liberty engine. Two of the Pomilio 
 brothers were brought to this country, and the 
 Alison shops at Indianapolis were turned over to 
 them. Their single-seater promised speeds around 
 150 miles an hour or better. 
 
 The Loening machines are also very promising.
 
 CHAPTER XVI 
 
 THE PROBLEM OF THE NIGHT-BOMBING MACHINES 
 
 THE problem of choosing types of night-bomb- 
 ers, and developing and putting them into pro- 
 duction in this country, was even more baffling 
 than the problem of the smaller 'planes. It led 
 to even more public disapproval, because it was 
 chiefly the night-bomber that would realize the 
 popular desire to see the German hinterland pun- 
 ished and terrorized by the night-flying engines of 
 destruction, even as France and England had been. 
 Liberal provision for the big bombers was made in 
 the 1917 program, but the difficulties were so 
 great that the end of the war found a total pro- 
 duction of only about 120 of them. These slow, 
 enormously large, great-weight carrying machines 
 required two or three engines to propel them and 
 presented most difficult manufacturing problems. 
 The selection of types was practically limited to 
 the Caproni and the Handley-Page, each using 
 Liberty motors. On the whole, the Caproni bi- 
 
 162
 
 o
 
 Night-Bombing Machines 163 
 
 plane, using two Liberty engines, was probably re- 
 garded as the superior machine but it soon became 
 involved in a maze of negotiatory complications 
 regarding the rights, which caused the drawings 
 to be withheld indefinitely and blocked utilization 
 of the models that the first Italian air mission 
 brought to America in the fall of 1917. As the 
 Handley-Page drawings were obtainable, it was 
 decided to put it into production, anyway, though 
 it was well understood that its ceiling was low and 
 that the advance in anti-aircraft guns might soon 
 retire it. 
 
 The same old trouble as to drawings soon ap- 
 peared in regard to the Handley-Page. The first 
 set was received in August, 1917, but two complete 
 sets followed later from England and each involved 
 a change of practically all the parts. When it is 
 recalled that there are more than a hundred thou- 
 sand parts in each machine, the complications of 
 adaptation to manufacture appear as appalling. 
 The headquarters of the Handley-Page effort were 
 placed with the Standard Aircraft Corporation, 
 Elizabeth, N. J., but the manufacturing division 
 of the work was distributed. 
 
 On account of the enormous size of these ma- 
 chines with their wing spread of more than one 
 hundred feet it was evident that it would not be
 
 164 Wings of War 
 
 practicable to ship completely assembled machines 
 abroad. It was therefore decided to make the 
 parts in this country and ship them to an English 
 plant for assembling. Even the packing of the 
 parts so that they would withstand the vicissi- 
 tudes of shipping was a delicate matter. Inci- 
 dentally it may be said here that not only was this 
 packing wonderfully well done with the Handley- 
 Page parts but also with the De Haviland 4*5 that 
 were shipped to France, and the manufacturers 
 were cordially complimented on their fine work in 
 this respect. A contract was entered into with the 
 British Air Ministry for the erection of an assem- 
 bling plant at Oldham in Lancashire. It was ar- 
 ranged that the parts were to be collected prior to 
 shipment at a special warehouse of the Standard 
 Company, which was also to complete the erection 
 of ten per cent, of the machines for training use 
 in this country. 
 
 Liberty engines of the standard 12-cylinder type 
 furnished the power. 
 
 The fittings, often very intricate fabrications of 
 pressed steel, were almost all made by the Mullins 
 Company of Salem, Ohio. 
 
 The wood parts were supplied by the Grand 
 Rapids Airplane Company, which was a combina- 
 tion of the Grand Rapids furniture manufacturers,
 
 The De Haviland 9, Successor to the DH-4 
 
 The First American-Built Liberty-Caproni
 
 Night-Bombing Machines 165 
 
 whose great industry was thus brought into the 
 airplane effort. 
 
 Delays comparable to those of the smaller 
 'planes of foreign design beset the work from start 
 to finish. Aside from the engine installations, 
 there was the always present problem of inade- 
 quate and altered drawings. Finally the English 
 assembling plant was slow in building. When op- 
 erations were discontinued one hundred full sets of 
 parts had been shipped to England and seven com- 
 plete machines had been erected in this country, 
 the first one having been flown in June, 1918. 
 Of course, there was a great accumulation of parts 
 and production was in full swing. The following 
 facts regarding the American Handley-Page are 
 taken from official sources: 
 
 Power 2 Liberty I2's, 400 H. P. each 
 
 Cliinb to 7,000 feet . . . . 18 minutes, 10 seconds 
 Climb to 10,000 feet. . .29 minutes 
 Climb to 14,000 feet . . .60 minutes 
 Total weight 1 1 ,270 pounds 
 
 On the trials from which these figures were 
 derived the machine did not carry guns, ammuni- 
 tion, or bombs but did carry seven men, 390 gal- 
 lons of gasoline, and twenty gallons of oil. 
 
 Engineers from the Handley-Page Company were
 
 i66 Wings of War 
 
 brought from England to assist in the Handley- 
 Page development in this country, but between 
 vacillating advices from the front and the compli- 
 cations incident to redesign for American pro- 
 duction, progress was very slow toward the stage 
 of quantity production. Like many other war 
 machines it can only be said of the Handley-Page 
 that it was just getting into its stride when the 
 signing of a piece of paper in Compiegne brought 
 to an end hostilities and all that unimaginably 
 great volume of production that America had 
 planned and wrought for a war that might have 
 lasted years longer. 
 
 It was not until January I, 1918, that tentative 
 agreements were made with the Caproni interests 
 for the production of their night-bomber in the 
 United States. 
 
 Soon thereafter Captain d'Annunzio with four- 
 teen expert Italian workmen arrived in this coun- 
 try and undertook to redesign the Caproni biplane 
 to take three Liberty motors. Unconscionably 
 long delays ensued. These were partly due to the 
 changes that were made in the organization of the 
 Signal Corps, which left the executive impaired 
 for a time, and partly to the difficulties in securing 
 the hearty cooperation of the Italian military 
 mission with the American plants which were
 
 Night-Bombing Machines 167 
 
 working on the Caproni. The Fisher Body Com- 
 pany, of Detroit, was entrusted with the major 
 part of the Caproni job and early made all its 
 arrangements with characteristic rapidity and 
 thoroughness, but it was not until the war was 
 over that the production stage was approached, 
 though a few samples had been completed. The 
 Fisher brothers would not have believed in June 
 that the end of the year would find them still shy 
 of production, but they had to go through the 
 same old story that has been told and retold of 
 the tasks of naturalizing foreign machines for 
 American production. In tests at Mineola, L. I., 
 September 21, 22, 1918, the American-made Cap- 
 roni made the following records: 
 
 TEST No. i TEST No. 2 
 
 Speed at ground level 100 mi. per hr. 103.2 mi. per hr. 
 
 Climb to 6,500 feet 16 min. 18 sec. 14 min., 12 sec. 
 
 Climb to 10,000 feet 33 min., 18 sec 28 min., 42 sec. 
 
 Climb to 11,200 feet 49 min. 
 
 Climb to 13,000 feet 46 min., 30 sec. 
 
 Total weight 12,904 pounds 12,350 pounds 
 
 Glenn L. Martin early offered his services to the 
 Aircraft Board and the Signal Corps and to him 
 was assigned the designing of a powerful bombing 
 machine which in size would be somewhat between 
 the two-place day bombers and the great night-
 
 i68 Wings of War 
 
 bombers. In fact, it was the intention of the 
 authorities to have Martin produce a large and 
 powerful machine for day bombing, with a very 
 high ceiling and exceptional speed, but on account 
 of its size it is here classed with the night-bombers. 
 Mr. Martin received very promptly an order for 
 four experimental machines, each using two Lib- 
 erty motors. This order was placed early in 1917. 
 Mr. Martin is one of the leaders of American 
 aeronautical engineering. He had every assistance 
 from the Government and he was able to surround 
 himself with a competent organization in the 
 Glenn L. Martin Company of Cleveland and yet 
 it took him about a year to bring out his first 
 machine. This fact is referred to only to indicate 
 that American dependence for aircraft could be 
 based only partly on American engineering and 
 established manufactories of aircraft. 
 
 The first official test of one of these machines 
 was made in October and aroused the greatest 
 enthusiasm. Although its wing spread was only 
 seventy-five feet, which was much less than that 
 of- the Handley-Page, its bomb-carrying capacity 
 was not much less. Its ground level speed of 118 
 miles an hour was markedly greater than that of 
 the Caproni or the Handley-Page and it was evi- 
 dent that its ceiling of probably more than eigh-
 
 Night-Bombing Machines 169 
 
 teen thousand feet would be greater than that of 
 the Caproni. Had the war continued the Martin 
 would probably have been the basis of the future 
 American heavy bombing squadrons. 
 
 Although the Martin bomber did not reach the 
 production stage in time to be a factor in the war, 
 the time and effort spent on it have not been 
 wasted. It can be used for mail and express carry- 
 ing and the transportation of freight and passen- 
 gers. It can carry eleven passengers or in lieu of 
 them a ton of mail. The air service is using the 
 Martin machine for training purposes and is equip- 
 ping it for forest border and coast service work. 
 
 Thus in the night-bombers, as in practically 
 every other feature of the aircraft construction 
 policy, these two things were done: (i) the most 
 suitable designs were taken up; and (2) American 
 designs were encouraged. All available American 
 engineering ability was utilized in some way in 
 designing and developing and at the same time 
 British, French, and Italian engineers were brought 
 to this country, either to adapt their existing 
 designs to the Liberty engine and American pro- 
 duction processes, or to work out new designs in 
 the American environment. 
 
 The results of the preliminary tests of the 
 Martin bomber, which follow, are interesting to
 
 170 
 
 Wings of War 
 
 compare with the corresponding figures for the 
 Handley-Page and the Caproni, given above : 
 
 TEST No. i 
 
 TEST No. 2 
 
 Speed at ground level H3-3 mi. per hr. 118.8 mi. per hr. 
 
 Climb to 6,-soo feet 10 min., 45 sec. 7 min. 
 
 Climb to 10,000 feet 21 min., 20 sec. 
 
 Climb to 15,000 feet 
 
 Total weight 9663 Ibs. 
 
 14 min. 
 
 30 min., 30 sec. 
 
 8137 Ibs.
 
 0) 
 
 .a 
 
 I
 
 CHAPTER XVII 
 
 AIRPLANE PRODUCTION RESULTS 
 
 WHEN one is disappointed in his own perform- 
 ance as compared with hopes and ambitions, there 
 is a sort of consolation in finding that at least he 
 did better than some of his fellows. We didn't 
 produce 22,000 airplanes and all the extra parts 
 that are the equivalent of many thousands more 
 in the twelve months between July I, 1917 and 
 July i, 1918. In those first twelve months, how- 
 ever, we did make 6146 airplanes of all kinds. 
 There are no figures at present available for 
 French and Italian or for German production. 
 But according to the Lockhart report of Novem- 
 ber ist, quoted in "Aircraft Production Notes" 
 issued by the Bureau of Aircraft Production, it 
 appears that in the calendar year 1915, which 
 could correspond in aircraft production evolution 
 to our fiscal year 1917-1918, the British Army and 
 Navy production was only 2040 machines and that 
 not until 1916 did it equal the American first war 
 year production for the army alone. In 1917 
 
 171
 
 172 Wings of War 
 
 British production attained to 14,400 'planes. In 
 1918 the British turned out after four years 30,000 
 machines and we 11,815 after one year, but had it 
 not been for the armistice we would have produced 
 12,808. We were headed for a production of 4000 
 'planes a month by April, two years after our en- 
 try into the war. Our engine production was much 
 further advanced and was probably going at the 
 rate of twice as much as French and British output 
 combined when the war ended. Our October rate 
 of production of 'planes was actually at the rate of 
 20,000 a year. Two years before, outside of one 
 plant, we were not making 50 airplanes a year. 
 
 As to 'planes actually in service at the front, it is 
 nard to get figures that may be relied on . The Chief 
 of Air Service, American Expeditionary Forces, es- 
 timated on July 30, 1918, that the Germans had 
 2592 machines in service at the front, and the Aus- 
 trians 717. The relative standing of the Allies as 
 of November, 1918, as given by Lockhart and as 
 estimated by the American Air Service follows : 
 
 LOCKHART'S REPORT AIR SERVICE 
 
 AS OF OCT. i, 1918 EST. Nov. n 
 
 France 3609 3600 
 
 Britain 3641 2100 
 
 United States 1032 860 
 
 Italy 1017 600
 
 Airplane Production Results 173 
 
 These figures or, at least, those of the American 
 Air Service are of fully equipped machines ready 
 for service and do not include replacement ma- 
 chines at the front or in reserve or training ma- 
 chines. The smallness of the numbers in actual 
 service in all countries as compared with total pro- 
 duction is worthy of note. To maintain one 'plane 
 in action eight had to be made yearly. 
 
 On account of the rapidly rising volume of pro- 
 duction and the ten thousand or twelve thousand 
 first-class flyers that the United States would have 
 had in the spring of 1919, the outlook was that it 
 would have taken the lead by a large margin. 
 England and France had probably about reached 
 the limit imposed by lack of human material.
 
 CHAPTER XVIII 
 
 THE STRIVING FOR SPRUCE 
 
 THE effort to obtain the equipment for mastery 
 of the air was more than 'planes and engines. It 
 was also a thousand and one things that went with 
 them to outfit a 'plane for service. And for 'planes 
 and engines and for all the other things it was not 
 only a struggle to make, but a struggle to find, 
 procure, or devise the raw materials. 
 
 The Equipment Division (Aircraft Production 
 Bureau) early grasped the significance of materials 
 and accessories for aeroplanes. From the very 
 start Colonel Deeds and his associates made 
 prompt and bold decisions and put forth extra- 
 ordinary efforts to stimulate and organize the pro- 
 duction of the indispensable raw materials both 
 for the United States and for the Allies. This 
 work was foundation building and, therefore, its 
 importance and magnitude were not appreciated, 
 being obscured from public view in matter-of- 
 course ordinary commercial preparation of raw 
 
 174
 
 The Striving for Spruce 175 
 
 materials plus the extraordinary production for war. 
 The decisions as to what was needed were made 
 quickly and as quickly carried into effect. From 
 the cotton fields of the Sea Islands and the Impe- 
 rial Valley of California to the somber and gigantic 
 forests of the Pacific Northwest and the towering- 
 stack industrial centers of the east, the country 
 was searched and combed to devise and produce, 
 and with hot haste, all the varied and numerous 
 material needed. 
 
 The struggle royal was for spruce. To get spruce 
 was no mere matter of telephoning the lumbermen 
 to ship it. The spruce for airplanes must be of the 
 best nature grows and it must be treated with the 
 greatest care. As splicing was little resorted to at 
 first it had to be obtained in single pieces of the 
 length of the wings. 
 
 Spruce was an international problem. All the 
 Allies required it. It was the wood par excellence 
 for the framework of 'planes. On its successful 
 production in abundant quantities depended not 
 only the fate of our own embryonic program but 
 likewise the programs of France, Britain, and Italy. 
 The Pacific Northwest was the principal source of 
 supply for the world. It had been logged commer- 
 cially in connection with fir and sometimes other 
 woods. Now came such a demand for it in quan-
 
 176 Wings of War 
 
 tity and also in quality that it must be logged on 
 its own account. Trees of the proper quality had 
 to be searched out in the dense and tangled forests 
 of the Pacific slope of Washington and Oregon. 
 The principal stand of spruce was in the remote 
 fastnesses of Clarke County, in the southwestern 
 corner of Washington. To reach it roads had to 
 be slashed through the dank and dripping wilder- 
 ness and whole forests scarred and even ruined to 
 obtain the coveted white wood. 
 
 At first it was thought that the lumbermen of 
 the Northwest would be able to meet the situation 
 by their own efforts. Unfortunately the lumber 
 industry of this section was prostrated in the 
 spring and summer of 1917 by a great strike. It 
 was partly a strike of organized labor and partly 
 of the I. W. W., but the latter succeeded in domi- 
 nating the movement for sinister and even hostile 
 purposes. All lumber production in the North- 
 western region was held up and there were many 
 acts of savage sabotage. Moreover, the mills were 
 not equipped to cut the straight-grained lumber 
 required and they did not have men skilled in the 
 selection and analysis of logs to secure the maxi- 
 mum amounts of suitable lumber from each stick. 
 Again it was difficult to get the sawmill men to 
 take the pains to meet the exacting requirements
 
 The Striving for Spruce 
 
 of the government. Months dragged by and the 
 output amounted to only two and a half million 
 feet a month, as against requirements of ten mil- 
 lion feet. Finally the crisis arrived and extreme 
 measures were taken immediately. On recommen- 
 dation of the Aircraft Board the Chief of Staff of the 
 army issued an order on October 17, 1917, creating 
 the spruce production division of the Signal Corps, 
 with Colonel Brice P. Disque in command, with 
 headquarters at Portland, Ore. Colonel later 
 General Disque, put soldiers in uniform into the 
 forests and the mills more than twenty-five 
 thousand picked men and organized the Loyal 
 Legion of Loggers and Lumbermen, seventy-five 
 thousand strong, as the patriotic answer to the 
 I. W. W., including in it employers as well as 
 employees. Its principles were no strikes, fair 
 wages, and the meeting at any cost of the country's 
 war needs in spruce. On March I, 1918, the oper- 
 ators and the men entered into an agreement which 
 gave General Disque absolute power to settle 
 all differences. 
 
 Specifications were standardized and modified 
 to meet milling conditions as far as possible; fi- 
 nancial assistance was extended to operators who 
 needed it, "methods of instruction were agreed 
 upon and a price was fixed by the government for
 
 Wings of War 
 
 aircraft spruce, thereby stabilizing the industry 
 and definitely providing against delays from labor 
 disputes." Thus the I. W. W. were routed, and 
 peace and productivity attained and maintained. 
 The spruce forests were studied and mapped and 
 hundreds of miles of railroads and wagon-roads 
 were built to get out the logs. Farmers were en- 
 couraged to split or rive spruce that was available 
 on their lands, and a cut-up mill with a capacity 
 of 300,000 feet a day was erected in record time 
 at Vancouver, Wash. Experienced men entered 
 the Spruce Division as a means of satisfying patri- 
 otic aspirations to render service, and it became 
 more and more efficient. Order was brought out 
 of chaos and the spruce victory was won. The 
 airplane factories at home were amply supplied, 
 60,000,000 feet going to them and 120,000,000 
 feet being moved across a continent and an ocean 
 to back the gallant flyers of France, England, and 
 Italy. It is very hard to give an adequate idea of 
 all the difficulties that stood in the way of this 
 admirable consummation. Besides the local and 
 inherent difficulties there were great obstacles in 
 the way of railway transportation to be overcome 
 and even in procuring the logging and lumbering 
 equipment that was necessary to the purpose. 
 There was also the technical problem of the
 
 The Striving for Spruce 179 
 
 proper drying of the lumber by artificial means in 
 such a manner as to preserve its strength, the ordi- 
 nary commercial practice being to dry it so as to 
 assure retention of shape rather than of strength. 
 This problem was chiefly solved by the efforts of 
 the Forest Products Laboratory of the United 
 States Forest Service at Madison, Wis., which in 
 this and other wood-utilizing matters supplied the 
 underlying scientific principles of treatment. It is 
 asserted that in consequence American practice in 
 this respect was better than that of France and 
 England although the subject was a novel one in 
 this country when the spruce effort began. The 
 knowledge thus disseminated among the country's 
 woodworkers will have a lasting benefit for com- 
 mercial purposes. 
 
 As time went on, economical methods of utiliz- 
 ing the spruce were found, so that there was no 
 such wastage from the log as at first. Splicing 
 became general for the longer pieces and the re- 
 quired thickness was often attained by lamination, 
 that is by glueing together two or more pieces. 
 Where it had at first taken 5000 feet of spruce in 
 the rough to yield the 500 feet placed in the 'plane 
 eventually 1000 feet sufficed. It was also found 
 that fir and other woods could be substituted for 
 spruce, with care in preparation.
 
 i8o Wings of War 
 
 Somewhat similar problems were met with in the 
 matter of mahogany and other hard woods suitable 
 for propeller making, and the experience gained in 
 treating and handling these woods for aviation 
 uses will be of general benefit to the hardwood 
 industries. 
 
 The success of the aircraft producers in dealing 
 with the spruce problem, resulting as it did, in 
 keeping the European airplane industry abund- 
 antly supplied with an essential material, is a con- 
 spicuous example of the important contributions 
 that were made through their tireless efforts to the 
 Allied air effort in other form than that of Ameri- 
 can 'planes and engines. Our work was not only, 
 it should be remembered, to build up a military 
 aviation body of our own, but also to keep the 
 aviation corps of the Allies going.
 
 CHAPTER XIX 
 
 DEVELOPMENT AND PRODUCTION OF DOPE 
 AND COTTON FABRIC 
 
 ONE of the numerous difficulties that faced the 
 aircraft managers in the development on an ex- 
 tensive scale of a great technical and complicated 
 industry from the ground up was that of the fab- 
 ric which covers the wings. Previous to the entry 
 of the United States into the war the fabric used 
 for this purpose had been made almost entirely 
 from linen. Linen is made from a peculiar variety 
 of flax grown under certain favorable conditions 
 in Belgium, Russia, and Ireland. The Belgian 
 supply was of course cut off when Germany in- 
 vaded Belgium in 1914 and the Russian supply 
 which had always been precarious was also cut 
 off after the Russian revolution. Ireland then re- 
 mained as the only source from which flax could 
 be obtained for airplane linen for the Allies. A 
 further complication arose from the fact that 
 Great Britain used large quantities of flax in the 
 
 181
 
 1 82 Wings of War 
 
 manufacture of duck sheets and like materials. 
 However, until August, 1917, the British Govern- 
 ment representatives felt confident that a suffi- 
 cient supply of Irish linen would be available for 
 the American aviation program. Soon after that, 
 however, it became evident that the Irish supplies 
 were inadequate and could not be depended upon. 
 In truth it was not until after Mr. Peter Fletcher, 
 a large importer of linen, who was sent to England 
 as a direct representative of the Signal Corps to 
 procure aeroplane linen, reported the actual sit- 
 uation in Great Britain and Ireland, that it was 
 realized that the United States must produce its 
 own wing covering. As early as July, 1917, 
 Mr. Fletcher reported that far from being able to 
 meet American requirements the Irish mills would 
 not long continue to produce enough fabric for the 
 rapidly extending British aircraft manufacturing. 
 So correct was Mr. Fletcher's forecast that it 
 turned out that the cotton fabric originated in 
 America was eventually drawn on by the Allies 
 themselves, so short was the supply of linen. 
 This is but another of the numerous instances of 
 the way in which we supported the air fleets of the 
 Allies while struggling to create our own. 
 
 On the receipt of Mr. Fletcher's report, the 
 building program and the whole aviation enter-
 
 Dope and Cotton Fabric 183 
 
 prise seemed in danger from the lack of a single 
 material. As each one of the ordinary training 
 machines, or a fighting machine like the DH-4, 
 needed about two hundred and fifty yards of 
 linen and as the prospectus was for the construc- 
 tion of more than twenty thousand machines in 
 the first year, it can be seen how essential was an 
 abundant supply of a suitable fabric. 
 
 The Bureau of Standards came to the rescue. 
 For several months before war was declared on 
 Germany that Bureau of the Department of Com- 
 merce had been doing experimental work on air- 
 plane cloths; a large variety of fabrics had been 
 examined and several experimentally promising 
 cloths had been produced. As soon as it became 
 evident that America must find some other fabric 
 than linen for covering the sustaining surfaces of 
 airplanes the problem was put directly up to the 
 Bureau of Standards. There had been a decided 
 prejudice against cotton but that material seemed 
 to offer the only hope of sufficient quantities. 
 
 "It is long staple cotton or nothing!" the ex- 
 perts of the Bureau of Standards told the Equip- 
 ment Division of the Signal Corps. 
 
 Without waiting for experiments to show which 
 it would be, Colonel Deeds immediately placed 
 orders for $4,500,000 worth of long staple cotton.
 
 184 Wings of War 
 
 "It may be all off the market to-morrow," he 
 said. "It is this or nothing consequently, we 
 will buy it all." 
 
 It did not take thirty minutes to decide on this 
 venture. 
 
 General Cormack, of the British Military Mis- 
 sion, is quoted as saying that the creation and pro- 
 duction of the type of cotton growth that is "at 
 least the equal of the best aeroplane linen" was 
 the greatest contribution in the way of raw mate- 
 rial that America made to the joint aeroplane effort. 
 All credit should be accorded for this prompt 
 decision but the scientific men of the wonder- 
 working Bureau of Standards (which filled many a 
 deadly industrial breach in the course of the war) 
 who conducted the experiments and the scientist 
 of the Department of Agriculture who investigated 
 long staple cotton nine years ago, must not be 
 overlooked. 
 
 The experiments resulted in two grades of cot- 
 ton airplane cloth: Grade A with a maximum 
 weight of 4^ ounces per square yard and mini- 
 mum tensile strength of 80 pounds per inch and 
 Grade B with a maximum weight of 4 ounces per 
 square yard and a minimum tensile strength of 
 75 pounds. A gratifying development as produc- 
 tion was attained was that Grade A turned out to
 
 Dope and Cotton Fabric 185 
 
 have a strength of 85 to 90 pounds. After Feb- 
 ruary, 1918, this grade was used altogether, for 
 the additional strength more than offset the 
 slightly increased weight. As soon as it was cer- 
 tain that the new cotton fabric would be acceptable 
 for that purpose the equipment division of the 
 Signal Corps insured itself against any eventu- 
 ality by purchasing 15,000 bales of Sea Island cot- 
 ton, the long staple of which best adapted it to 
 the purpose. Orders for 20,000 yards of cotton 
 airplane cloths were issued in September, 1917. 
 By March of the following year the production 
 had reached 400,000 yards a month; in May, 
 about 900,000 yards and at the termination of 
 hostilities the rate of production was approxi- 
 mately 1,200,000 yards a month. Special manu- 
 facturing facilities had to be provided by the tex- 
 tile manufacturers who were engaged on this work 
 and it kept about 2600 looms busy. Altogether 
 10,248,355 yards of this fabric were woven and 
 after August, 1918, the use of linen, which had 
 been declining in proportion as the production of 
 cotton increased, was entirely discontinued. 
 
 The substitution of cotton for linen was one of 
 the American achievements of the war, and is now 
 considered not as a makeshift substitution but as 
 providing a material at least equally good as linen.
 
 1 86 Wings of War 
 
 It is doubtful whether linen will ever again be used 
 in large quantities for the manufacture of airplane 
 wings in this country. 
 
 Dope was another manufacturing problem. It 
 is the preparation which is applied on all the fabric 
 surfaces of the airplane in order to stretch the 
 cloth tight and to fill the fabric and thereby create 
 a smooth, waterproof surface. Over this dope 
 ordinary spar varnish is applied to protect the sur- 
 face. The dope problem was not so much one of 
 difficulty of making material in this country as it 
 was of interfering with the British munitions re- 
 quirements, as acetone, which is the basis of cor- 
 dite, an explosive extensively used by the British, 
 is required in manufacturing one kind of dope. 
 There are two kinds, namely, nitrate dope, which 
 is made from the nitrate cellulose and wood chem- 
 ical solvents, and acetate dope which is made from 
 acetate and wood chemical solvents, including 
 acetone. The latter kind had an advantage in 
 that it is slow burning, whereas nitrate dope burns 
 very rapidly. The latter not being exposed to 
 incendiary bullets when used on training 'planes 
 would do for them but acetate dope was indis- 
 pensable to fighting 'planes, and nitrate was the 
 chief form of dope at the time of our entry into 
 the war. The Allied governments, especially the
 
 Dope and Cotton Fabric 187 
 
 British, had been consuming the major part of the 
 output of acetone and like products, and it was a 
 matter of grave concern to the British Government 
 when it found what extensive quantities of ace- 
 tone would be required in the manufacture of Ameri- 
 can aircraft. It was estimated that the American 
 demand would be twenty-five thousand tons for 
 the 1918 program alone, whereas the requirements 
 of the Allies and those of domestic commerce 
 would be alone greater than the total supply ordi- 
 narily available. Faced with this situation it was 
 therefore determined that the government should 
 take control of efforts looking toward increased 
 production. A new kind of dope had to be devised 
 and this necessity led to many and diverse chem- 
 ical researches, for there was not only a shortage 
 of acetate of lime, but also of the refined ingre- 
 dients needed in the dope such as cellulose, ace- 
 tate, acetic anhydride, and glacial acetic acid. It 
 was necessary to commandeer the entire existing 
 supply of acetate of lime, it being the base from 
 which acetone is made, and also to commandeer 
 other supplies needed for this work. By means of 
 the government's active interest and cash advances 
 ten large chemical plants, representing an invest- 
 ment of about twenty million dollars, were es- 
 tablished at Collinwood, Tenn.; Tyrone, Pa.;
 
 i88 Wings of War 
 
 Mechanicsville, New York; Lyle, Tenn.; Fremont, 
 Mo.; Sutton, W. Va.; Shelby, Ala., and Terre 
 Haute, Indiana. 
 
 As a result of these efforts, 1,324,356 gallons of 
 dope were manufactured during the war, which was 
 enough to meet all requirements. Had the war 
 gone on the new plants which the government had 
 started would have been able of themselves to meet 
 all requirements without further commandeering 
 of privately owned plants. Pending the comple- 
 tion of the new plants, the entire available supply 
 of chemicals required in the manufacture of dope 
 was moved and allocated to the different countries 
 by the wood chemical section of the War Indus- 
 tries Board, the British undertaking to act for 
 themselves as well as the other Allies. An arrange- 
 ment was also made between the Signal Corps 
 and the British War Mission by which the Amer- 
 ican and British governments were to share equally 
 losses resulting from the erection of the new 
 government plants, or otherwise.
 
 CHAPTER XX 
 
 MACHINE GUNS FOR AIRCRAFT 
 
 IN view of the many fighting uses made of air- 
 planes during the war it is not easy to realize that 
 the war in Europe had lasted about a year before 
 they were seriously taken as a new means of com- 
 bat. Their uses for observation and scouting were 
 so important and so much relied on that little 
 attention was given to their possible combat uses. 
 Indeed, stories are told of hostile aviators con- 
 fining their inimical operations to shaking their 
 fists at each other. The early use of offensive 
 weapons was confined to revolvers; then service 
 and automatic rifles and shotguns were taken up 
 and grenades and darts were used. The first step 
 in the use of machine guns was to take up an ordi- 
 nary ground gun, the observer operating it from 
 his shoulder. As early as 1912 a machine gun had 
 been successfully operated from an airplane in 
 this country but it was an isolated experiment. 
 At the outbreak of the war the French had a few 
 
 189
 
 190 Wings of War 
 
 heavy airplanes that were designed to carry ma- 
 chine guns, but the fact is that as a bearer of weap- 
 ons not much attention was paid to the airplane 
 until the war had been going on a year. One rea- 
 son why little attention was given to fixed arma- 
 ment was that the pilot could make little use of a 
 gun firing forward because of the interference of 
 the propeller; and, indeed, on account of his atten- 
 tion being required in the operation of the 'plane 
 he could make little use of a weapon that was 
 discharged laterally. It was not until the idea of 
 a synchronizer was developed, whereby a fixed 
 machine gun was so timed in the discharge of its 
 projectiles that they passed between the rapidly 
 revolving blades of the propeller, that the airplane 
 machine gun era was entered. Before that fixed 
 machine guns were mounted above the 'plane at a 
 sufficient height to clear the arc of the propeller 
 with their fire. It was difficult to reload a gun 
 thus placed and so, to bring it down to the pilot's 
 level, the synchronizer was developed. At first 
 the bullets were actually discharged blindly 
 through the revolving propeller, those that struck 
 the blades being deflected by properly placed steel 
 plates, or else the chance of destruction was taken, 
 as it was found that several bullets might pass 
 through a blade before it would break. The
 
 Machine Guns for Aircraft 
 
 Germans appear to have been the first to put the 
 synchronizing device into general use, with their 
 Fokker monoplanes in 1915. Even as late as 1917 
 machine guns were used without synchronizers. 
 It is not possible to say who hit on the idea of so 
 regulating machine gun fire that the bullets would 
 pass between the propeller blades, but credit is 
 quite generally given to the famous French aviator, 
 Roland Garros. 
 
 Aircraft armament was even stranger to Ameri- 
 cans at the beginning of the war than aircraft 
 themselves. Neither the ordnance department nor 
 the Signal Corps had any experience with machine 
 guns worth mentioning. They were not used on 
 the few 'planes that were sent to the Mexican 
 front during the Villa disturbances. Nothing was 
 then known in this country about the installation 
 of aircraft armament, although the Savage Arms 
 Company was manufacturing Lewis flexible air- 
 craft guns for the British Government. To show 
 how difficult a task the matter of armament was 
 to producers who knew nothing about it, some at- 
 tention should be given to the special requirements 
 of aircraft machine guns. As little can be done in 
 the way of overhauling guns while in the air, the 
 jamming of a gun may be fatal, as in that case the 
 aviator is left at the mercy of the enemy. The gun
 
 i9 2 Wings of War 
 
 must be so constructed that it will work in any 
 position. To prevent jamming the ammunition 
 must be exceptionally excellent. Also a machine 
 gun to be adapted for use in the air must have a 
 very high rate of fire, as the gun is usually on the 
 target for only a second or two, and every possible 
 shot counts. With ground guns a rate of fire of 
 500 shots a minute is considered enough, but air- 
 craft guns deliver from 950 to 1000 bullets a min- 
 ute. The aircraft guns are simpler than ground 
 guns in one respect, and that is that water-cooling 
 is not required for them as the conditions for 
 aerial combat do not necessitate continuous firing 
 for a long period. 
 
 Single-seater machines use only fixed guns which 
 are so placed that the barrel is parallel to the axis 
 of the airplane and the gun is therefore aimed by 
 aiming the 'plane, and the guns of such machines 
 must, as previously explained, shoot through the 
 propeller. The flexible guns that are used in the 
 rear seat of two-place machines are, of course, not 
 fired through the propeller and do not require syn- 
 chronizing devices but they do have special mounts 
 which permit them to be fired in any direction. 
 It is interesting to note that all the flexible air- 
 craft guns in use among the Allies have adopted 
 the principle of the Lewis machine gun, which was
 
 Machine Guns for Aircraft 193 
 
 invented by Colonel Isaac N. Lewis, U. S. A., 
 retired. Experts say that the Lewis gun principle 
 of a drum magazine is better adapted to flexible 
 guns than any type of belt feed. In this respect 
 the Allies had an advantage over the Germans 
 whose flexible gun used the belt feed. 
 
 The only fixed gun used by the French and 
 British at the time of our entry into the war was 
 the Vickers, the entire production of which in the 
 United States had been already contracted for by 
 the Allies for use in the ground form. 
 
 Through efforts of officers of the equipment 
 division of the Signal Corps the Marlin- Rockwell 
 Corporation in New Haven, Conn., developed a 
 fixed type of aircraft gun. The Marlin was chosen 
 because it was the only gun then available. Not- 
 withstanding marked opposition an order for 
 Marlin guns was placed in the fall of 1917 and 
 resulted in giving the American air service a suf- 
 ficient supply of fixed guns. 
 
 Had it not been for this order other departments 
 of the service would have been seriously handi- 
 capped. For example, on June 24, 1918, the chief 
 of ordnance presented cable No. 1168, from the 
 A. E. F., demanding 7220 machine guns for tank 
 use. Within twenty-four hours 500 guns were 
 shipped by express to France from the air service 
 
 13
 
 194 Wings of War 
 
 depot at Fairfield, Ohio, and the remaining 6720 
 guns were forwarded in the next two weeks. The 
 Lewis aircraft guns were first ordered on Decem- 
 ber 19, 1917. Deliveries began in February, 1918, 
 with about 1500 guns a month and by October 6000 
 guns had been delivered. However, the Marlin gun 
 was used at all times as the American fixed air- 
 craft machine gun. The first order was placed by 
 the Signal Corps on September 25, 1917, and over 
 37,500 were turned out before December, 1918, as 
 many as 7000 guns being produced in one month. 
 Satisfactory as the Marlin gun was the Browning 
 aircraft machine gun was considered superior, 
 chiefly because it had the high rate of fire of about 
 950 shots a minute and was extremely reliable and 
 very accessible. In time it would probably have 
 replaced the Marlin and all other fixed machine 
 guns. 
 
 The Marlin gun shoots a 3O-caliber bullet at the 
 rate of 600 to 650 shots a minute. American air- 
 craft guns were equipped with the hydraulic type 
 of gun control known as the Constantinesco, with 
 some special American adaptations. In this type 
 of gun the impulse of the cam of the aircraft 
 engine is transmitted to the gun through a system 
 of tubes containing glycerine under high pressure. 
 This device is so effective that at maximum fire
 
 Machine Guns for Aircraft 195 
 
 1300 shots per minute can be fired between the 
 blades of a propeller turning at the rate of 1600 revo- 
 lutions per minute, without striking the propeller 
 blades. Even four guns have been fitted to one 
 'plane and so controlled that none of the bullets 
 hit the blades. At the time of the signing of the 
 armistice 6827 of the Constantinesco gears had 
 been manufactured in this country and shipped, 
 although nothing whatever was known of their 
 nature or process of manufacture at the time we 
 entered the war. 
 
 Early in the war (with the Boiling Commission) 
 130 selected American mechanics were sent abroad 
 to familiarize themselves with the many and vari- 
 ous problems of aircraft mechanisms. One of these 
 was named Nelson and to him was assigned the 
 study of the synchronizers. He undertook the 
 development of a mechanical synchronizer, carry- 
 ing on this work in the experimental laboratory of 
 the Signal Corps and the Aircraft Production 
 Bureau at McCook Field, Dayton. He succeeded 
 in getting a machine that will permit of more 
 rapid firing and the concentration of the bullets in 
 a smaller arc than is possible with any other type 
 of synchronizer. Using the Nelson control device 
 it is possible to fire a Browning machine gun 
 through a four-blade propeller without hitting any
 
 196 Wings of War 
 
 of the blades. More than one hundred of these 
 synchronizers were completed, and had the war 
 gone on they would have superseded the hydraulic 
 synchronizer in both American and foreign practice. 
 Enormous quantities of ammunition were re- 
 quired for these guns and it was being made at the 
 rate of ten million rounds a month. Besides the 
 ordinary projectile ammunition there had to be 
 developed tracer cartridges which leave a trail of 
 smoke behind them, armor-piercing cartridges, and 
 incendiary cartridges containing a charge of yellow 
 phosphorus and intended to set fire to whatever 
 they strike. Many of the armament sundries such 
 as the metallic disintegrating cartridge belts of the 
 machine guns, the details of fitting the guns to the 
 'planes, the providing of proper sights, electric 
 heaters for keeping the guns warm at high alti- 
 tudes, etc., constituted very considerable prob- 
 lems of development of manufacture in themselves.
 
 CHAPTER XXI 
 
 RADIO TELEPHONE AND AERIAL PHOTOGRAPHY IN 
 CONNECTION WITH AERIAL OBSERVATION, 
 THE CHIEF FUNCTION OF MILITARY AVIA- 
 TION 
 
 THE thrilling duels and other combats of the air 
 which have marked this war as being conducted 
 in a third element which was not the medium of 
 attack or defense in preceding wars have centered 
 public attention on aerial combat as the end of 
 military aircraft. Attacks on troops by airplanes 
 flying low and raking them with machine-gun fire 
 have led to their being called the cavalry of the 
 air. Audacious bombing expeditions against en- 
 emy bases and far behind the lines have led them 
 to be considered as a sort of substitute for artillery. 
 No doubt the popular idea of the program of 
 building an aircraft fleet whose vessels would be 
 numbered by the thousands was that they would 
 by means of bombing attacks on the enemy become 
 one of the chief agencies of winning the war. While 
 
 197
 
 198 Wings of War 
 
 military men admit the great value of airplane 
 offensives on account of their effect on the morale 
 of enemy troops and civilian population, the pre- 
 vailing view among them seems to be that the 
 chief military use of the airplanes is as a means of 
 securing information as the modern scout. Time 
 might have proved this to be an erroneous view, as 
 it has in the course of history overthrown many a 
 technical view. However, this was so strongly the 
 conviction of the French army that it is authori- 
 tatively stated that the reason the French did so 
 little in the way of bombing German towns and 
 cities, even when their own communities were 
 being attacked nightly, was their judgment that the 
 results were not worth the losses of men and ma- 
 chines that they would entail. Their conception 
 of the airplane was that it was for observation and 
 direct combat work at the front. Our own officials 
 were largely of the French view. Whether this be 
 the right or the wrong position is immaterial at the 
 moment, except that it supplies a justification of 
 the fact that the only American made service 
 'planes that reached the front were of the ob- 
 servation type, though also adapted to combat. 
 In other words, the type of machines that we 
 sent to France was the type that was consid- 
 ered most important, though it was not the
 
 Function of Military Aviation 199 
 
 type whose exploits got on the front pages of 
 newspapers. 
 
 "The basis of all war-time aviation is the obser- 
 vation air service," says Lieutenant Colonel Lewis 
 H. Brereton, U. S. A., in some notes on the activ- 
 ities of the American air service on the Western 
 front, "and the proportions of other branches of 
 the air service to this arm are always related to the 
 necessities of the special situation, that is, the 
 strength of the opposing air service, the kind of 
 operations which is in progress, etc. Our experi- 
 ence is that the proportion of one pursuit squadron 
 to one squadron of any other type, that is obser- 
 vation or bombardment, was sufficient, but not 
 ample. . . . The three general classes of mili- 
 tary aviation can be headed under the titles obser- 
 vation, pursuit, and bombardment. . . . Our 
 best observation 'planes were the Salmson and the 
 DH-4, Liberty motor. The Salmson was furnished 
 by the French and was equipped with a nine-cylin- 
 der radial stationary motor of about 275 H. P. 
 It was a very staunch, reliable ship and exceedingly 
 popular both with the French and with us. The 
 DH-4, of course, developed nearly 400 H. P. and 
 was a very capable ship. 
 
 "The DH-4 was al so use d for bombardment. 
 These 'planes carry two men, pilot and observer,
 
 200 Wings of War 
 
 and three or four machine guns. Two of these 
 guns are mounted on the tourelle or revolving 
 mount and can be fired in almost any direction by 
 the observer in the rear of the pilot ; the remaining 
 guns are fired by the pilot in one direction only, 
 straight ahead. Right here you can see the enor- 
 mous advantage of the two-place ship over the 
 one-place ship in combat. The monoplane can 
 only fire one way, that is heading straight, as the 
 guns are fixed. The observer of the bi-place ma- 
 chine can fire all the time his opponent is in range 
 except when the opponent gets into one of his 
 so-called d ad spaces; that is, in front, under or 
 over his wings, or under his tail. I would myself 
 be perfectly willing to engage in combat against 
 two enemy i >ursuit ships, if I have a good observer, 
 in either a -H or a Salmson bi-plane." 
 
 The air r ;rvice observation is the most impor- 
 tant intelligence agent of an army, according to 
 Lieutenant Colonel Brereton. The high command 
 looks to it for the greater part of its information 
 concerning the movements and dispositions of the 
 enemy and also for information regarding his inten- 
 tions. The latter class of information, which is 
 exceedingly important, is derived largely from 
 aerial photography, and Colonel Brereton illus- 
 trates this function by giving the outlines of the
 
 2 
 
 CO 
 
 
 O
 
 Function of Military Aviation 201 
 
 manner in which the French High Command ascer- 
 tained the German intentions in the offensive be- 
 ginning July 15, 1918. For two weeks before that 
 day French aviator-observers had systematically 
 photographed the whole of the Marne salient 
 Rheims, Chateau-Thierry, Soissons and by 
 studying the data thus obtained the French Gen- 
 eral Staff was able to forecast the German drive 
 within forty-eight hours and ascertain almost 
 exactly the sector of the effort. The enemy's 
 intentions were disclosed by the appearance of 
 new second-line defenses, by new supply x depots 
 and ammunition dumps and the enormous increase 
 of traffic on the highways, the pushing of ammuni- 
 tion dumjps nearer to the front, new telephone 
 lines and roads ; and finally as an indication of the 
 imminence of the attack "a sudden great increase 
 in the activities on the roads immediately behind 
 the German front lines ; the construction of ramps 
 and new roadways leading from battery positions 
 and trenches to facilitate the egress of troops ; and 
 one particularly damning indication of attack, the 
 fortunate location by a French aerial observer of a 
 German pontoon train, located not far from the 
 Marne and just north of Dormans." With this 
 and other information the French High Command 
 was able to make such dispositions that the Ger-
 
 202 Wings of War 
 
 man offensive was not only stopped in its tracks 
 but was immediately followed by an Allied offen- 
 sive that reversed the whole course of the war and 
 continued until the Germans acknowledged defeat. 
 
 Observation is just as important during a battle 
 as before it. The work of the observation 'planes 
 while the battle is progressing consists among 
 other things of keeping headquarters informed of 
 the progress of its own front lines, as well as the 
 locations of the infantry. This involves flying 
 very low for visual observation and identification 
 of units and is very perilous as the observer is 
 taking chances with the barrage fire of his own 
 troops, to say nothing of the flock of pursuit 
 'planes that is seeking to destroy him, with the 
 result that the two-place observation 'plane has to 
 fight an unequal battle before it can get away 
 with its information. 
 
 The use of bombing 'planes in battle is well 
 illustrated by Colonel Brereton's account of the 
 greatest aerial concentration that took place dur- 
 ing the war, viz., at Damvilliers, during the Amer- 
 ican offensive of the Argonne-Meuse, which began 
 on September 26th. The reports of the observers 
 indicated a tremendous concentration of German 
 artillery and infantry at Damvilliers in the center 
 of a forest eight kilometers behind the German
 
 Function of Military Aviation 203 
 
 front lines, apparently preliminary to a German 
 counterattack. Of what follows Colonel Brereton 
 says: 
 
 "After a consultation with the High Command, 
 the Chief of Air Service (Brigadier General 
 William Mitchell) gave directions to our bombard- 
 ment pursuit aviation and to the French aviation 
 under our command for a concentrated bombing 
 attack on the woods in which Damvilliers was 
 located. Shortly after the order was issued, one 
 of the largest formations of airplanes ever assem- 
 bled passed from army headquarters on its mis- 
 sion. It consisted of 352 ships, French and 
 American, composed of French and American bom- 
 bardment squadrons with pursuit squadrons for 
 protection. More than thirty- two tons of bombs 
 were dropped in the space of less than thirty 
 minutes. The attempt of the German aviation to 
 block this maneuver resulted in a spirited air 
 fight in which the enemy 'planes were cleared from 
 the air, having had twelve of their 'planes de- 
 stroyed and several others shot down out of control. 
 Our losses were one 'plane shot down on our front 
 lines and eight aviators wounded, none missing. 
 The counter-attack was completely dispersed and, 
 although the German casualties are not known, 
 photographs taken of the area bombed the follow-
 
 204 Wings of War 
 
 ing day showed very extensive demolishment of the 
 greater part of the area and it was subsequently 
 known that parts of two German divisions had 
 been concentrated in this area." 
 
 Viewed in this light the chief purpose of a mili- 
 tary airplane is to act as a conveyance for the 
 observer or scout and for the instruments he 
 requires in doing his work. Chief among these 
 are the radio telephone and the photographic cam- 
 era, the one being voice and ear and the other the 
 eyes of the airplane. Both underwent tremendous 
 development during the war, and the American 
 contribution to such development was very impor- 
 tant, especially in respect to the radio telephone, it 
 being generally conceded that the American appa- 
 ratus was best. The radio telephone is of great 
 use, not only as a means of communication between 
 the units of a flying squadron but chiefly in con- 
 nection with directing artillery fire. Radio teleg- 
 raphy was further developed than radio-telephony 
 at the beginning of the war and when the United 
 States entered it the former had been very suc- 
 cessfully adapted to aerial use. The Signal Corps 
 was especially at home in this work and thousands 
 of radio telegraph sets were promptly provided. 
 In fact aerial radio work had been closely studied 
 and carefully developed since as far back as 1911.
 
 Function of Military Aviation 205 
 
 Previous to the application of aerial electrical 
 communication, indirect artillery fire, which is 
 practically the only kind of artillery fire in modern 
 warfare, was controlled in so far as it was con- 
 trolled at all from airplanes or balloons by 
 various forms of visible signals, which were ob- 
 viously inadequate. 
 
 Before the United States entered the war little 
 had been done to adapt the radio telephone to 
 aerial uses. About that time both the French and 
 English began to make considerable headway, and 
 our specialists worked unremittingly on the idea. 
 It is superior to radio-telegraphy as used in the air 
 because it is communication by word of voice 
 instead of by signals. It provides the means of 
 conveying full instead of skeletonized information 
 both to the ground and to other airplanes. The 
 subject is so technical that no attempt will be made 
 to describe the apparatus here. Some of the prob- 
 lems that had to be solved to utilize radio tele- 
 phony were the overcoming of the drowning effects 
 of the thunderous noise of the motor, the rush of 
 the air, and the rattle of machine guns; the reduc- 
 tion of the weight of the apparatus to smallest 
 possible minimum ; the avoidance of all fire hazard 
 from the electric current; the obtaining of such 
 a simplicity that flyers could operate it easily
 
 206 Wings of War 
 
 and without long instruction and the overcoming 
 of the effects of airplane vibration on the appa- 
 ratus. As to the first problem, only, it may be 
 remarked that a way was found literally to strain 
 the sound waves of the voice from those of the 
 motor, so that the observer could transmit his 
 voice, though when talking into the transmitter 
 he could not hear himself. 
 
 As far back as 1910 Col. C. C. Culver of the 
 Signal Service, looking upwards at a flock of eleven 
 airplanes demonstrating at an aviation meet, at 
 Belmont Park, remarked that if they could only 
 talk to each other another wonder would have 
 been accomplished. Eight years later, Colonel 
 Culver, who had kept his eye on this objective all 
 the time, was to have the proud distinction of de- 
 monstrating in France the complete superiority of 
 the American method of adapting radio telephony 
 to aerial uses, Largely due to Colonel Culver's 
 insistent interest in the subject of radio communi- 
 cation as applied to airplanes, the successful 
 demonstration of long distance radio telephony for 
 naval uses by the engineers of the Bell system, and 
 particularly of the Western Electric Company 
 in 1915, was followed by successful studies of the 
 utilization of the radio telephone for various mil- 
 itary purposes, such as communication with and
 
 View of Observer's Cockpit of DH-4, Showing General Arrangement 
 
 of Apparatus, Including Wireless Sending and Receiving 
 
 Outfit, and Scarff Mounts for Lewis Guns
 
 Function of Military Aviation 207 
 
 between ships at sea. Dr. Frank B. Jewett, 
 chief engineer of the Western Electric Company, 
 and his assistant engineers, including Edward B. 
 Craft and E. H. Colpitts, were finally interested 
 in concentrating their attention on the radio tele- 
 phone as adapted to airplane service. Then there 
 came a day when the Aircraft Board and the Joint 
 Army and Navy Technical Board were wonder- 
 ingly introduced to the achieved apparatus at 
 Dayton, to the work of developing which they had 
 given every possible encouragement. After that 
 demonstration, however, it was necessary to con- 
 vince the active army of the merits of the new 
 means of communication. Then after the army 
 had approved it, came the work of manufacturing 
 the radio-telephone sets and installing them on 
 the planes. 
 
 "It would take volumes to describe the innumer- 
 able experiments and heartbreaking failures before 
 the first real successes," says Mr. Craft in an 
 article on the subject. "At length a head set in- 
 side an aviator's helmet was devised, which would 
 exclude the noise of the airplane engine and the 
 rushing air. A brilliant line of experiments, largely 
 at the hands of J. P. Minton, resulted as well in a 
 transmitter or microphone, which possessed the 
 remarkable quality of being insensitive to wind
 
 208 Wings of War 
 
 and engine noises, and at the same time very 
 responsive to the tones of the voice. Then three 
 solid months of the hardest kind of work was 
 necessary to iron out all the kinks and get the 
 thing in shape so that it might be considered a 
 practicable device for the everyday use of other 
 than experts. 
 
 "Finally in October, 1917, we reached the point 
 where we thought it was time to spring it on the 
 A. E. F. and accordingly Colonel Culver was sent 
 abroad with several trunkloads of the apparatus to 
 show our people overseas that we had not been 
 asleep on the job and had a new tool for their use. 
 In early December the next historical event took 
 place at South Field, Dayton, Ohio. To those of 
 us who were mixed up in this little affair those were 
 three days which we will never forget. Colonel 
 Carty and Colonel Jewett were in the party which 
 was made up of admirals, generals, foreign repre- 
 sentatives and experts galore, all willing to be 
 shown but decidedly skeptical. 
 
 "It must be remembered that the idea had not 
 yet been told to any but the wild enthusiasts who 
 had been living with the job for the past six 
 months. Pilots are, to say the least, fussy about 
 what is loaded into the 'planes they are to fly, to 
 say nothing of the trailing wires which serve as
 
 Function of Military Aviation 209 
 
 antennae. Designers and constructors hold much 
 the same view, so it took a lot of maneuvering 
 and diplomatic jockeying to get our stuff aboard 
 and into the air. Finally, just about dark on the 
 evening before the fatal day we did get one ma- 
 chine into the air, and found that the apparatus 
 worked. 
 
 "The plan was to have two 'planes in the air 
 at once and for the official party to listen in at a 
 ground station located on the top of a hill on 
 Moraine Farm near the field. That night we all 
 congregated in one of the rooms of the hotel, 
 worked out our scenario, and held a rehearsal. I 
 must confess that I didn't sleep very well that 
 night. Next day we were out at the field bright 
 and early, fussing around trying to keep busy until 
 it was time for the big show. Upon arrival of the 
 exalted ones we showed them the apparatus in 
 the 'planes and explained what it was expected 
 to do. 
 
 "They went to our little station on the hill, 
 where we had rigged up a loud-speaking receiver 
 connected to the wireless apparatus so that all 
 could hear without the use of head sets. The 
 'planes left the ground and after what seemed an 
 interminable length of time we got the first sounds 
 in the receiver which indicated that they were 
 14
 
 210 Wings of War 
 
 ready to perform. The spectators were only mildly 
 interested and some seemed a bit bored. 
 
 "Suddenly out of the horn of the loud speaker 
 came the words, 'Hello, ground station. This is 
 'Plane No. I speaking. Do you get me all right?' 
 The bored expression immediately faded and looks 
 of amazement came over all their faces. 
 
 "Soon we got the same signal from No. 2 and 
 the show was on. Under command from the 
 ground the 'planes were maneuvered all over that 
 part of the country. They were sent on scouting 
 expeditions and reported what they saw as they 
 traveled through the air. Continuous conversa- 
 tion was carried on, even when the 'planes were 
 out of sight, and finally upon command they came 
 flying back out of space and landed as directed. 
 
 "From that moment the radio telephone was 
 sold." 
 
 Another form of radio adaptation enables the 
 observer to locate his position with reference to 
 certain fixed points by means of radio signals sent 
 from the land. In this radio compass development 
 as well in radio telephony the United States was 
 well in the lead both in engineering and in pro- 
 duction. 
 
 Photography is essentially the means of aerial 
 observation. The sensitive plate can detect at
 
 Function of Military Aviation 211 
 
 10,000 feet what the eye does not perceive; more- 
 over, it records as it observes. Aerial photog- 
 raphy made the recent war unlike all others, 
 because it supplied such accurate information of 
 enemy dispositions and lines of entrenchments, 
 roads, supply bases, etc., that each side was about 
 as well informed of such enemy affairs as of its own. 
 Combined with direct visual observation it also 
 made it very difficult to move large bodies of 
 troops to new positions without detection. Thus 
 surprises became 'very difficult, and were only 
 possible by night marches and the utilization of 
 weather unfavorable for observation. The chief 
 value of aerial photography lies in its map-making 
 possibilities, and cameras were developed that 
 automatically mapped the underlying country as 
 the airplane moved over it, even at great heights. 
 Aerial photography militarily applied was en- 
 tirely new at the beginning of the war in Europe 
 but it developed with great rapidity, so that when 
 the United States came in it was utterly unpre- 
 pared in this regard, the nations at war having, of 
 course, kept developments and inventions to them- 
 selves. Apparatus had become very refined, and 
 highly specialized and complicated. Some work 
 in aerial photography had been done in this coun- 
 try by Arthur Brock, Jr., of Philadelphia; the
 
 212 Wings of War 
 
 G. E. M. Engineering Company of Philadelphia, 
 and the Eastman Kodak Company of Rochester, 
 N. Y. Also the Signal Corps and the Bureau of 
 Standards had given some study to mapping cam- 
 eras. The Allies soon communicated their knowl- 
 edge and experience, but it was necessary for 
 our manufacturers to make the equipment, and 
 improve on it if possible. Both these things 
 were done, and before the war was over, 1164 
 automatic aeronautical cameras had been made 
 complete with their spring suspensions to offset 
 vibration, motors, and other accessories. 
 
 This figure refers only to the mapping cameras. 
 Large quantities of hand cameras and photo- 
 graphic accessories of every kind were supplied. 
 The amount of supplies procured and forwarded 
 was prodigious. During the Argonne advance in 
 four days alone the American observers took 
 100,000 pictures of the enemy line. The number 
 of prints of these pictures is not given but in the 
 British service as high as 280,000 prints were 
 issued in a single month. It was the excellence 
 of the photographic equipment as well as the pro- 
 vision of a sufficient number of airplanes to hold 
 and use them, that enabled General Pershing to 
 state that "no army ever went out with the infor- 
 mation as to what was in front of it as the Ameri-
 
 Function of Military Aviation 213 
 
 can army did in St. Mihiel and the Argonne." 
 This authoritative statement is sufficient answer 
 to the captious critics who were wont to assert 
 bitterly that our army fought "blind" in France. 
 
 The development and making of the peculiar 
 sort of lens required to take detail photographs 
 at great heights, the devising of ray filters to over- 
 come haze, were scientific, technical, and mechani- 
 cal problems of the utmost difficulty. And yet, it 
 has been well said that the cameras themselves 
 were only the beginning of successful aerial photog- 
 raphy. Among the articles and supplies that had 
 to be provided in great quantity were lenses, paper, 
 plates, chemicals, tanks, trays, printing machines, 
 sterescopes, and traveling dark rooms. In the 
 month of October alone more than 1,500,000 half 
 sheets of photographic paper were shipped and 
 300,000 dry plates, more than 20,000 rolls of film 
 and forty tons of chemicals. . 
 
 The placing of photographic and radio appa- 
 ratus in the airplane was one of the problems that 
 gave the 'plane designers trouble. And these were 
 only a part of the equipment for which the right 
 place and sufficient space had to be obtained. It 
 was nothing less than a complex, time-killing 
 puzzle. And if placing and the necessary design- 
 ing and redesigning were a limitation on produc-
 
 214 Wings of War 
 
 tion it is an equally important fact that the limit 
 of effective production of the 'planes themselves 
 depends on the accessories. An airplane without 
 the military accessories is as useless as an untrained 
 civilian is as a soldier. 
 
 So, making airplanes for the war was not only a 
 matter of engines, wings, and fuselages, but it was 
 that of photographic equipment, oxygen appa- 
 ratus, aerial navigating instruments, radio, guns, 
 bombs and bombing apparatus, rockets, flares, 
 special clothing and personal equipment for the 
 aviator, and much besides. The development or 
 adaptation of all this apparatus as well as its man- 
 ufacture had to go forward parallel to that of the 
 airplanes themselves. In fact, the problems of all 
 sorts were so complex and interrelated that the 
 aircraft managers stoically abandoned as a thing 
 impossible an explanation that would adequately 
 answer the criticisms that were showered upon 
 them. One had to be on the inside to understand, 
 and being there he was condemned to suffer in 
 bitter silence uninformed fault-finding that was 
 at times little short of scurrilous.
 
 CHAPTER XXII 
 
 AIRPLANE BOMBS, AERIAL PYROTECHNICS, AND 
 AVIATORS' PERSONAL EQUIPMENT, ETC. 
 
 IT is not possible in a brief work to discuss in 
 detail the important subject of airplane equipment. 
 Machine guns and photographic equipment have 
 been described briefly and a short account of air- 
 plane bombs, aerial pyrotechnics, and aviators' 
 personal equipment such as clothing and the oxy- 
 gen apparatus will be given in this chapter. 
 
 Bombs had been dropped from airplanes during 
 the Italian Tripolitan campaign and American 
 aviators serving with Mexican civil war forces had 
 used them. The German Zeppelins were the first 
 aircraft to attempt to use bombs systematically. 
 At first, however, they were not very effective 
 because not properly designed and incapable of 
 accurate aiming. Owing to the fact that an air- 
 plane is moving rapidly when the bomb is dis- 
 charged it describes a curve as it falls, and must 
 therefore be released before the airplane is directly 
 
 215
 
 2i6 Wings of War 
 
 over the object it is desired to hit. The proper 
 shape is somewhat like that of a torpedo with a 
 fin-tail to hold the bomb in the proper position. 
 Traps or release mechanisms must be provided 
 that will detach the bombs from their storage 
 places beneath the fuselage, or the wings, or in the 
 case of the large bombers from inside the fuselage. 
 To promote accuracy of projection, bomb sights 
 must be provided. These devices are ingeniously 
 arranged so that when adjusted to height, speed, 
 and wind, the bringing of two sighting points into 
 line gives the aim. During the war there were pro- 
 duced in the United States 8371 of these sights, 
 following the English Wimperis model. Releasing 
 traps were provided for all the machines that were 
 designed to carry bombs. 
 
 Three general kinds of bombs were made, viz., 
 demolition, fragmentation, and incendiary. The 
 demolition bombs, used against buildings and earth- 
 works, were made in weights of 50, 100, 250, 500, 
 and looo pounds. Such bombs are made with a 
 light steel casing filled with T. N. T. or some other 
 high explosive and have a detonating mechanism 
 that is made ready for action on contact at the 
 moment it is released from its position. Most of 
 these bombs were of the 100- and 25O-pound sizes. 
 The fragmentation bombs usually weigh about
 
 
 .11 
 
 Is 
 
 J3 .. 
 
 S fe 
 
 5 
 
 Q 
 
 O 
 
 ' 
 
 s
 
 Airplane Equipment 217 
 
 20 pounds, have a thicker case than the demoli- 
 tion bombs and are arranged to explode a few 
 inches above the ground. These bombs are used 
 against personnel and depend for effect upon the 
 scattering of the fragments. Incendiary bombs 
 weigh about 50 pounds and are loaded with oil 
 emulsion, thermit, and metallic sodium which upon 
 the explosion of the bomb burn with intense heat 
 for a few minutes. These bombs are used par- 
 ticularly against ammunition dumps and for the 
 purpose of starting fires. 
 
 Had the war continued another six months, the 
 American aircraft producers would have treated 
 the Germans to a surprise, comparable only to the 
 introduction of poisonous gas and tanks as weapons 
 of war. A small and inexpensive automatic air- 
 plane, fitted with a specially adapted Sperry gyro- 
 scope as a stabilizer had been secretly devised and 
 developed and conclusively tested. Loaded with 
 several hundred pounds of T. N. T., it would follow 
 a set course to a distance of forty or fifty miles or 
 more and then, at the predetermined place, would 
 shed its wings, the fuselage plunging to the ground 
 as a huge bomb. All preparations had been made 
 to manufacture and send 100,000 of these engines 
 of destruction to the front. It was confidently 
 believed that they would have turned the German
 
 2i8 Wings of War 
 
 bases, supply depots, mobilization centers, lines of 
 communication, and garrison posts, into a chaos of 
 fire and explosion unprecedented in those respects 
 even in the world war. 
 
 Pyrotechnics were used during the war by the 
 aerial forces to signal to and from the ground or 
 back and forth in the air. For this purpose service 
 airplanes carry a signal pistol known as the "Very " 
 pistol. Its ammunition consists of cartridges not 
 unlike those of a shotgun shell but larger, and are 
 in effect the ordinary Roman candle. The cart- 
 ridges come in three colors, red, green, and white, 
 and by using these colors in different combina- 
 tions a large number of different signals is possible. 
 The stars are visible in the daytime as well as at 
 night. Special use of the pistol at night time is to 
 enable the pilot to signal his approach to the home 
 landing-ground. The pistols have also been used 
 to enable the aviator to carry out his orders to 
 destroy his machine in case of landing in enemy 
 territory by firing into inflammable parts of the 
 airplane. This is one of the few items of airplane 
 equipment that was purchased abroad and was 
 not made at home. To facilitate night-landing, 
 wing-tip flares are also used. These consist of a 
 small cylinder of magnesium material in a metallic 
 holder, one being fitted under each lower wing of
 
 Airplane Equipment 219 
 
 the 'plane, and can be ignited by means of an elec- 
 tric current. In making a night-landing these 
 flares when lighted brilliantly illuminate the 
 ground beneath. 
 
 The airplane flare proper is used for illuminat- 
 ing enemy territory during night-bombing raids. 
 Each weighs about thirty-two pounds and is con- 
 tained in a cylindrical sheet-iron case, the illumi- 
 nating charge being capable of giving a light of 
 thirty-two thousand candle power for about ten 
 minutes. The flare is attached to a silk parachute, 
 so attached to the airplane that it can be easily 
 released. Immediately after discharge from the 
 case the parachute opens and so lowers the flare 
 slowly to the ground, the light from it brightly 
 illuminating a large area underneath. An inci- 
 dental effect of the flares is to dazzle the eyes of 
 anti-aircraft gunners so that their aim is very in- 
 accurate. They are also of value in obtaining 
 aerial photographs at night. American production 
 of these flares was just starting when the war 
 terminated. 
 
 Even such apparently insignificant matter as 
 obtaining suitable clothing for aviators was in 
 effect one of no little difficulty. At first like almost 
 everything else connected with the aviation effort 
 it was not known just what was the proper apparel
 
 220 Wings of War 
 
 equipment for an aviator, or a balloonist. It was 
 necessary that the clothing should be as warm as 
 possible without being cumbersome, also that it 
 should be strong and durable and that each part 
 should be adapted to the others. The head-gear 
 consisted of a woolen hood of double thickness, 
 having between its layers an electrically heated 
 unit connected with an air-driven generator on the 
 'plane, by copper wires that also extended through 
 the suit proper. A soft leather helmet lined with 
 fur was worn over this and the face was entirely 
 covered with a leather mask lined with wool with 
 an opening for the eyes over which was fitted a 
 pair of goggles. When using the radio a special 
 radio helmet was worn in place of the fur-lined 
 helmet, so fashioned as to hold the receivers of the 
 wireless telephone over the ears. 
 
 The body clothing consisted of a one-piece flying 
 suit extended from the feet to the throat, belted 
 and tightly buttoned at ankles and wrists and lined 
 throughout with fur. One of the little big prob- 
 lems of the war was the securing of enough of 
 the right kind of fur for this purpose. Chinese 
 Nuchwang dogskin was chosen for this purpose and 
 it demanded practically all of the skins that could 
 be obtained in both this country and China, and 
 nearly five hundred thousand of such skins were
 
 *v 
 
 ''tfr^A' s*,/4 
 
 "^,^1 
 
 ^/4/-<Jk 
 
 Aviator's Oxygen Mask in Position, Ready for Use
 
 Airplane Equipment 221 
 
 obtained. Through these suits between the fur 
 and outer covering were placed wire cables ending 
 in snap-fasteners at the wrists, ankles and neck 
 to which could be attached a silk covered wire 
 leading to the electrical-heating units in the gloves, 
 moccasins, and helmets, all of which were elec- 
 trically warmed. For the hands, besides the elec- 
 trically heated gloves was provided a pair of 
 muskrat fur gauntlets extending well up the arms 
 and so designed as to allow the trigger fingers to re- 
 main in a fur-lined pocket or be withdrawn from it 
 when necessary without removing the glove. On the 
 feet were worn both electrically heated socks and 
 electrically- warmed moccasins extended well over 
 the calf of the leg and lined with heavy sheep 
 wool. Of course, there were many other items 
 of aviators' clothing, such as sweaters, leather 
 coats, fur-lined coats, and two styles of hard 
 helmets used mostly by students and obser- 
 vers, and many different kinds of goggles. As 
 a result of the great care taken in these mat- 
 ters it was generally acknowledged that our 
 flyers were by far the best and most efficiently 
 equipped at the front. More than 50,000 fur- 
 lined flying suits, over 100,000 leather helmets, 
 more than 100,000 leather coats, and over 80,000 
 goggles were included in a personal equipment
 
 222 Wings of War 
 
 program that involved an expenditure of more 
 than $5,000,000. 
 
 In high-flight work it was also necessary for the 
 aviators to wear oxygen masks made of rubber 
 containing a transmitter allowing the aviator to 
 speak as well as hear by wireless. This mask was 
 attached to a tube leading to a tank of oxygen 
 carried in a convenient place in the 'plane and so 
 adjusted as automatically to feed to the aviator 
 different amounts of oxygen as different altitudes 
 were attained. 
 
 This oxygen apparatus is so important that it 
 is not possible to give a sufficient account of it in 
 a brief space. Its purpose was to supply aviators 
 with the right proportions of oxygen when flying 
 in the rarified air of great altitudes, which the 
 increasing range of anti-aircraft guns made neces- 
 sary, it having been found that the efficiency and 
 health of the airmen were greatly impaired on 
 account of lack of enough oxygen at high altitudes. 
 The American aircraft producers had to take a hand- 
 made apparatus of French design and adapt it to 
 American manufacturing methods, while also im- 
 proving it. It was the same story as with almost 
 everything brought from Europe for American 
 adaptation, and presented the usual problems and 
 difficulties, all of which were successfully overcome.
 
 I 
 
 u 
 
 c 
 
 o 
 I 
 
 .5 
 S 
 
 ol 
 
 
 i 
 
 e
 
 Airplane Equipment 223 
 
 The work began in January, 1918, quantity pro- 
 duction was attained in May and by October one 
 thousand sets were being turned out monthly, the 
 shipments to France totaling near four thousand. 
 
 The realization that the varying degrees of oxy- 
 gen at different heights was the major influence on 
 the efficiency of aviators led to searching studies of 
 the adaptability of aviators to different heights and 
 resulted in a remarkably efficient method of deter- 
 mining the aviator's limitations, so that aviators 
 came to be put in different classes according to the 
 heights at which they could successfully fly. 
 
 One of the aviation accessories successfully de- 
 veloped by the Signal Corps equipment division 
 was the machine-gun camera which was used to 
 teach aviators how to shoot accurately with ma- 
 chine guns. Obviously, in practice aviators cannot 
 have airplanes for targets with actual machine-gun 
 bullets. This raised the question as to how stu- 
 dents could be prepared in advance for the actual 
 experiences of battles in the air. The machine-gun 
 camera was the answer. It is simply a regulation 
 Lewis machine gun with a roll of films sustituted 
 for the cartridge belt. The aviator works the gun 
 precisely as if he were firing bullets, but instead 
 of doing so he takes pictures of his target and the 
 film record shows the accuracy of his aim. This
 
 224 Wings of War 
 
 was a bit of war preparation unknown to the 
 Germans and they therefore marveled at the accu- 
 rate marksmanship of our cub aviators in their first 
 battles in the air.
 
 CHAPTER XXIII 
 
 MILITARY BAIXOONS 
 
 IT is an interesting fact that the development 
 of the airplane to its present degree of effective- 
 ness has not held back the utilization of the sta- 
 tionary balloon in warfare. Concentration of 
 attention on the airplane undoubtedly resulted in 
 the Allies giving less attention to mobile balloons 
 or dirigibles than they would otherwise, and pre- 
 vious to the use of helium gas because of its non- 
 inflammability, as well as for other reasons, the 
 general policy of the Allies in this respect was most 
 wise. On the whole, the German Zeppelins were 
 not a military success, though more because of their 
 inflammability than for any other cause. They 
 were of great aid to the German fleet in the North 
 Sea, as scouts; and with the use of helium and 
 other improvements will loom large in the future 
 of aeronautics. 
 
 Early in the war it was found that for observa- 
 tion purposes anchored or kite balloons had 
 is 225
 
 226 Wings of War 
 
 tain advantages over the rapidly moving airplanes, 
 and toward the end they were more relied on than 
 airplanes for control of artillery fire. 
 
 France and England had devoted some atten- 
 tion to the modern type of observation balloon 
 the stream-line or so-called "sausage" type, and 
 Germany a good deal, but as in all other things 
 pertaining to aerial warfare America was much 
 behind. The German Drachen type, though 
 crude compared with later developments, was 
 much superior to anything the Allies had, and the 
 numbers of them possessed by the Germans gave 
 them a distinct advantage in control of artillery 
 fire in the first part of the war. Captain Caquot 
 of the French army met the situation with a kite 
 balloon that had superior stability in high winds 
 and that could operate at higher altitude than the 
 Drachen, and it came into general use by the 
 armies and navies of France, England, and America 
 and was imitated by the Germans. The somewhat 
 grotesque appearance of these balloons is due to 
 the air lobes attached to the rear third of the gas 
 envelope, which are filled with air by the action 
 of the wind and give the balloon stability. The 
 Caquot also has an ingenious device for offsetting 
 the leakage of gas, with a view to keeping the sur- 
 face of the envelope firm and symmetrical. It
 
 A Navy 4 ' Blimp " Non-Rigid Dirigible in the Air
 
 Military Balloons 227 
 
 consists of an air chamber within the gas-contain- 
 ing envelope which fills and expands as the gas 
 pressure decreases on account of leakage. 
 
 The United States army had used one captive 
 balloon on the Mexican border, and though 
 European developments in balloons had been 
 closely watched there was little manufacturing 
 capacity for them in this country and many quan- 
 tity manufacturing problems had to be dealt with. 
 So, the heavily burdened Equipment Division of 
 the Signal Corps, later to become the Bureau of 
 Aircraft Production, had to wrestle with another 
 great task. Only two or three balloons a month 
 were then being made, and plans and specifica- 
 tions for the approved types were lacking. Bal- 
 loon making was the opportunity of the rubber 
 companies for patriotic service and they responded 
 energetically and cordially, the Goodyear and 
 Goodrich companies at Akron, Ohio, taking the 
 lead and being followed later by the United States 
 Rubber Company, the Firestone Tire & Rubber 
 Company, the Connecticut Aircraft Company, and 
 the Knabenshue Manufacturing Company. 
 
 A Caquot "R" type of kite balloon is 93 feet 
 long and 28 feet at its greatest diameter, thus re- 
 quiring a great yardage of rubberized cloth for the 
 envelope; in fact an output of 10 balloons a day
 
 228 Wings of War 
 
 required 600,000 yards of special balloon cloth, 
 the toil of many hundreds of weavers, and the use 
 of 3200 looms. Balloon cloth, proper, is made of 
 cotton and must be made with the greatest care 
 with 140 threads to the inch both ways. Very 
 little such cloth had been made in the United 
 States and because of the difficulties of training 
 weavers, the wastage from imperfections, and the 
 small possible output per loom, manufacturers 
 were reluctant to undertake contracts. At first 
 the wastage was as high as 60 per cent., but 
 with increasing skill was reduced to 10 per cent. 
 To see that perfect cloth was produced the gov- 
 ernment and the manufacturers had to em- 
 ploy and train hundreds of inspectors. Thous- 
 ands of men had to be instructed in making the 
 cloth. 
 
 It was a tedious process to develop and expand 
 this cloth-making industry, but by November, 
 1918, the American capacity had increased from 
 enough for two balloons a day in April, 1917, to 
 sufficient for ten a day. Moreover, the output was 
 always abreast or ahead of the balloon-making 
 program. In ordinary times such an industrial 
 achievement would have been a seven-days' won- 
 der, but it was lost sight of in the whole mountain 
 range of unusual manufacturing deeds during the
 
 Military Balloons 229 
 
 war, and entirely overlooked in judging the aircraft 
 managers. 
 
 After the cotton cloth is made it has to be rub- 
 berized in order to make an air-tight fabric. This 
 meant the development of another specialized in- 
 dustry. The fabric consists of a film of specially 
 made rubber between sheets of the cloth, and the 
 outside cloth ply is covered with a rubber compound 
 which serves as protection against moisture and the 
 actinic rays of the sun and for a camouflage. In 
 blending the cotton cloth and the rubber film, the 
 fabric is sometimes put through the presses thirty- 
 five or forty times. While American manufactur- 
 ing of this fabric followed European practice in the 
 main, there were some departures and the Ameri- 
 can article was regarded as superior, chiefly be- 
 cause it was slower burning. This was an important 
 consideration for it was the common fate of obser- 
 vation balloons to be set afire sooner or later and 
 a slow-burning fabric gave the observers more time 
 to take to their parachutes and escape. 
 
 A necessary accompaniment of the balloons was 
 the machinery and apparatus to operate them suc- 
 cessfully. Windlasses had to be built for the pur- 
 pose of letting up and pulling down the balloons, 
 and these had to be of great strength and high 
 speed. As the French had developed a satisfactory
 
 230 Wings of War 
 
 windlass, it was put into production in this coun- 
 try to be on the safe side while the American types 
 were being developed. This task was successfully 
 undertaken by the James Cunningham, Sons & 
 Company, of Rochester, N. Y. The first American 
 windlasses were operated by steam, but later elec- 
 tricity and gasoline motors were used. The best- 
 known gasoline type had one motor to operate the 
 windlass and the other to move it from place to 
 place. This kind could pull down a balloon at a 
 rate of sixteen hundred feet a minute, and travel 
 unimpeded at the rate of twenty miles an hour, or 
 at five miles with the balloon in tow. The United 
 States Army Balloon School developed one type 
 of windlass, which was manufactured by the 
 Me Keen Motor Car Company of Omaha, and an- 
 other was developed and made by the N. C. L. En- 
 gineering Company of Providence, R. I. 
 
 Another manufacturing achievement worthy of 
 mention was the designing and making of a special 
 anchor cable, which also enclosed the telephone 
 wire cable by means of which the observer com- 
 municated with the ground, thus doing away with 
 separate telephone cables, which had been a great 
 nuisance. The Chas. A. Roebling & Sons Com- 
 pany and the American Steel and Wire Company 
 cooperated in the important work.
 
 6-Cylinder, loo-H. P. Rear Windlass Engine Caterpillar, Tractor Adapter, 
 for Towing and Controlling Observation Balloons 
 
 Caquot "Sausage" Balloon, Beginning Its Ascent 
 U. S. Air Service Photo
 
 Military Balloons 231 
 
 Hydrogen gas is the buoyant element with which 
 balloon envelopes were inflated. Before the war it 
 was manufactured in this country in only a small 
 by-product way, but the requirements for mil- 
 lions of cubic feet for the balloons were promptly 
 met by new government plants and the expan- 
 sion of private plants. Portable hydrogen gene- 
 rators for field use were also manufactured, but most 
 of the hydrogen was made in the United States 
 and shipped to the front in steel containers, of 
 which 172,000 were ordered and 90,000 made, 
 under a pressure of 2000 pounds to the square 
 inch. Before the armistice was signed the private 
 manufacturers alone had made and delivered near 
 18,000,000 cubic feet of hydrogen. The special 
 problems of the field generators were in themselves 
 manifold, as were those of many other balloon 
 materials and accessories, such as the parachutes, 
 rigging cordage, and "nurse" balloons, which car- 
 ried reserve gas for the service balloons. 
 
 As the war approached its end, the balloon sec- 
 tion achieved its most original success, in the prac- 
 tical utilization of non-inflammable helium gas, a 
 fact that was a military secret until after hostilities 
 ceased, the gas being disguised verbally as "argon." 
 Using it instead of hydrogen, balloons and dirig- 
 ibles eliminated fire-risk from enemy action, light-
 
 232 Wings of War 
 
 ning, and whatever cause, thus overcoming the 
 chief obstacle to safe employment of airships. 
 Helium was known before the war, but its produc- 
 tion was so small and it was so costly, being worth 
 $1700 a cubic foot, that it was not to be immedi- 
 ately considered as a substitute for hydrogen. It 
 was known, however, that it was to be found in 
 small proportions in some of the natural gases of 
 the United States, and with financial assistance 
 from the Signal Corps, Navy, and Bureau of Mines, 
 the last two supervising the experiments, satisfac- 
 tory production was attained by the gas liquefac- 
 tion processes known as the Norton and those of 
 the Linde Air Products Company and of the Air 
 Reduction Company. So far had this work pro- 
 gressed that on the day the armistice was signed 
 147,000 cubic feet of helium were ready to be 
 loaded on ships for France, and a permanent plant 
 was building with a capacity for treating 5,000,000 
 cubic feet of natural gas daily, at an estimated cost 
 of ten cents a cubic foot for the realized helium. 
 At 100 per cent, efficiency the product would be 
 50,000 feet daily. 
 
 The Norton process was an entirely new system 
 of liquefaction of natural gas and was taken up 
 by the Bureau of Mines. The so-called Norton 
 plant was established at Petrolia, Texas. The need
 
 Military Balloons 233 
 
 for the cheap and abundant production of such a 
 gas as helium was so great that soon after work on 
 the Norton process was started the British sent 
 two high naval officers to the United States to 
 urge that the American Government use all pos- 
 sible means to rush the production of helium. 
 With a view to doing so, therefore, contracts were 
 made with the Linde Air Products Company and 
 the Air Reduction Company for the erection of 
 experimental plants at Ft. Worth, Texas. The 
 Linde Company began operations on March 6, 
 1918, and these were so successful that a large pro- 
 duction plant using the same process was under- 
 taken by the army, and this plant is of permanent 
 construction and will begin producing helium gas 
 at the actual rate of 30,000 feet a day and at a 
 cost of about five cents a foot, sometime in the 
 middle of 1920. The Air Reduction Company 
 plant went into operation on May ist, and while 
 it produced helium it was not so successful as the 
 Linde process. The Norton method is still in 
 the experimental stage, but if it should succeed 
 the cost will be lower than by either of the other 
 methods. To facilitate the production of helium, 
 the construction of a pipe-line was authorized from 
 Petrolia to the plants at Ft. Worth, Texas, and 
 steps were taken to conserve the gas production
 
 234 Wings of War 
 
 of the Petrolia pool, thus saving an enormous 
 amount of helium and extending the life of the 
 pool over a period of approximately ten years. 
 Helium has been found also in natural gases of 
 Kansas, Ohio, and Montana, and because of its in- 
 combustibility 500,000 cubic feet are wasted daily 
 in the United States. 
 
 An interesting fact about helium is that the 
 United States contains practically all of the known 
 utilizable sources. Col. A. L. Fuller of the Army 
 Air Service in an article in Air Service comments 
 that it is remarkable that an element once un- 
 known on the earth's surface, and originally dis- 
 covered in the sun, and one so rare before the war 
 that the largest quantity ever collected in one 
 place was approximately sixty cubic feet, should 
 now be used in the enormous quantities necessary 
 for balloon work. It is quite possible that the new 
 gas besides bringing buoyant airships into new 
 favor and great possibilities may have many scien- 
 tific and commercial uses. Already it has been 
 used to obtain lower temperatures than were pos- 
 sible by any other means. It is intended to locate 
 all possible sources of helium in the United States 
 and conserve them. "Helium" is described by 
 Colonel Fuller as "one of the most remarkable 
 gases. It is a light, monatomic gas and the light-
 
 I 
 
 o 
 
 O
 
 Military Balloons 235 
 
 est of rare gases. It is the last of the so-called 
 perfect gases to be liquefied, and it liquefies at a 
 lower temperature than any other gas. It is one 
 of the constituents into which radium breaks 
 down when undergoing a transformation which 
 accompanies radioactivity, particles of helium being 
 given off as the different types of the radium series 
 are changed." 
 
 An amusing incident of the helium research 
 work was that some members of Congress having 
 learned that Colonel Deeds and Commander 
 Atkins, having on behalf of the Aircraft Board 
 purchased the output of certain natural gas wells 
 in Texas of such a poor quality that it could not 
 be used to fry eggs, suspected some sort of corrupt 
 intention, and started an informal investigation 
 which, had it not been promptly nipped, might have 
 resulted in another formal Congressional investi- 
 gation of aircraft production. It was with consid- 
 erable difficulty that it was made plain to the legis- 
 lators, without betraying a supremely important 
 military secret, that the one reason why this gas 
 was desirable was its lack of heat production. 
 
 It is confidently held that the success attained 
 in perfecting methods of separating helium gas 
 cheaply will greatly widen the possibilities of 
 buoyant aircraft in peace as well as in war.
 
 236 Wings of War 
 
 The official statistics of the production of bal- 
 loons and accessories in the United States during 
 the war for the army alone are as follows : 
 
 April 6, 1917 November n, 1918 
 
 Balloons: 
 
 Type R, observation 642 
 
 Type M, observation 22 
 
 Type C, observation 7 
 
 Type J, observation I 
 
 Experimental observation 4 
 
 Supply balloons 129 
 
 Spherical balloons 10 
 
 Propaganda balloons 215 
 
 Total i',Q3O 
 
 Parachutes 285 
 
 Windlasses 50 
 
 Cable, feet ' 1,221,582 
 
 Gas equipment : 
 
 Hydrogen cylinders 89,225 
 
 Hydrogen, cubic feet produced by pri- 
 vate manufacturers 171634,353 
 
 Helium, cubic feet 147,000 
 
 The above production for the army provided, 
 not only for the requirements of A. E. F. and the 
 balloon schools in the United States, but permitted 
 furnishing a substantial quantity of this class of 
 equipment to the Allies.
 
 Military Balloons 237 
 
 The supply balloons mentioned in the above 
 table are simply "nurse" balloons under another 
 name. The propaganda balloons are small bal- 
 loons, carrying propaganda literature with an 
 automatic device for freeing printed leaflets and 
 pamphlets, and so arranged as to be self -destructive 
 when the balloon ultimately comes to earth. 
 These balloons were sent over the enemy lines 
 when the weather was favorable. 
 
 Although as yet little recognized, the balloon 
 providing achievements of the aircraft production 
 department constitute one of the industrial feats 
 of fame during the war. Beginning, like the air- 
 planes, from nothing, like their development too, 
 it attained a supreme place in this field of military 
 endeavor.
 
 CHAPTER XXIV 
 
 TRAINING FIELDS, CAMPS, AND SUPPLY 
 
 THE construction side of the mammoth aircraft 
 enterprise had not only to produce the flying 
 machines and other equipment for the use of the 
 fighting and training personnel but it had to pro- 
 vide sites and facilities for their use. When the 
 war began, there were only two government flying 
 fields in America. The training of 15,000 flyers 
 and the assembling and organizing of the 190,000 
 men of the flying service required an enormous 
 physical establishment, and the business of pro- 
 viding, acquiring, and preparing the fields, all sorts 
 of supplies for the men, their housing, and the shops 
 was in itself a task that would have sorely tried a 
 highly trained and developed industrial organiza- 
 tion. It involved at home and abroad an expendi- 
 ture of about $80,000,000 and everything had to be 
 done with feverish haste, which even when realized 
 seemed in the nervous tension of a war in which 
 every minute was supremely important, all too slow. 
 
 238
 
 Training Fields and Camps 239 
 
 Col. C. C. Edgar, on recommendation of Col. 
 Waldon, was put in charge of the Supply Division 
 to which this work was entrusted and he later 
 had as assistant Lieut.-Col. E. Lester Jones, 
 who was granted leave of absence from his posi- 
 tion as director of the U. S. Coast and Geodetic 
 Survey for this duty. The Supply Division was 
 established May 21, 1917, and in the next u 
 months it had undertaken 47 main projects and 
 completed 35 of them, not counting its work in 
 connection with the flying school and aviation 
 bases in France. 
 
 The home establishments included, in part, 15 
 single-unit flying fields, 4 double-unit fields, 3 con- 
 centration camps, 3 balloon schools, 5 supply 
 depots, 3 repair depots, I experimental station, 
 I radio laboratory, 3 mechanics' schools, I artillery 
 field, 4 acceptance parks, I quarantine camp, and 
 the permanent stations at Langley Field and San 
 Diego. These camps, depots, and schools were 
 located all over the country, from Mineola on Long 
 Island to San Diego, California, and from Arcadia, 
 Florida, to Minneapolis and St. Paul, though most 
 of the flying fields were in the southern part of the 
 country, for climatic reasons. 
 
 The following is a list of construction work com- 
 pleted or in progress about April 5, 1918:
 
 240 Wings of War 
 
 LOCATION DESCRIPTION EST. COST 
 
 Americus, Ga. 
 
 Souther Field I four-squad, camp $ 812,100 
 
 Souther Field Warehouse 400,000 
 
 Arcadia, Fla. 
 
 Carlstrom Field I four-squad, camp 812,100 
 
 Dorr Field I four-squad, camp 812,000 
 
 Belleville, 111., Scott Field, I four-squad, camp 1,680,529 
 
 Dallas, Tex., Love Field. . I four-squad, camp 929,100 
 
 Dallas, Tex Repair depot 551.500 
 
 Dallas, Tex., Concentra- 
 tion Camp Miniature range, building, 
 
 & sundry equipment for 
 
 existing buildings 16,766 
 
 Dayton, O Supply Depot 800,000 
 
 McCook Field Experimental sta 1,000,000 
 
 I eight-squad, camp, in- 
 cluding gunnery school. . 3,097,777 
 
 Fort Omaha, Nebr Balloon school 493,266 
 
 Florence Field Add'l balloon outfit unit. . 77,000 
 
 Fort Sill, Okla., Post 
 Field Aerial observers' camp. . . . 1,485,480 
 
 Fort Sill, Okla Balloon school 385,000 
 
 Fort Weed, N. Y Supply depot, addition to 
 
 building 47,000 
 
 Fort Worth, Tex. 
 
 Taliaferro, No. I I four-squad, camp 1,121,600 
 
 Taliaferro, No. 2 I four-squad, camp 1,007,100 
 
 Taliaferro, No. 3 I four-squad, camp 857,100 
 
 Houston, Tex., Ellington 
 Field I eight-squad, camp 2,130,900 
 
 Indianapolis, Ind Repair depot 582,000 
 
 Lake Charles, La i eight-squad, camp 2,266,600 
 
 Gerstner Field 
 
 Little Silver, N. J. 
 Camp Alfred Vail Radio laboratory 368,350 
 
 Lonoke, Arkansas, Eberts 
 Field I four-squad, camp 812,100 
 
 Memphis, Tenn., Park 
 Field , I four-squad, camp 1,769,600 
 
 Middletown, Pa Supply depot 613,000
 
 
 Captive Caquot "Sausage" Balloon
 
 Training Fields and Camps 241 
 
 LOCATION DESCRIPTION EST. COST 
 
 Mineola, L. I., Hazlehurst 
 
 Field i five-squad, camp; i con- 
 centration camp, and gen- 
 eral aviation supply depot $ 4,2 1 8, 149 
 
 Minneapolis, Minn Mechanics' school 150,000 
 
 Montgomery, Ala., Taylor 
 Field i four-squad, camp 812,100 
 
 Montgomery, Ala Repair depot 600,000 
 
 Morrison, Va Concentration camp 1,603,100 
 
 Mt. Clemens, Mich., Self- 
 ridge Field I four-squad, camp 2,903,203 
 
 Rantoul, 111., Chanute 
 Field i four-squad, camp 1,130,482 
 
 Richmond, Va Supply depot 1,000,000 
 
 Riverside, Cal I four-squad, camp 800,000 
 
 Sacramento, Cal i four-squad, camp 850,000 
 
 San Antonio, Tex., Kelly 
 
 Field i eight-squad, camp; i con- 
 centration camp; 2 stor- 
 age warehouses 3498,555 
 
 Brooks Field I four-squad, camp 837,100 
 
 Balloon School 144,480 
 
 San Diego, Cal., Rock- 
 well Field Temporary buildings, con- 
 struction of bridge and 
 part of temporary bldgs. 1,164,200 
 
 Waco, Tex. 
 
 Rich Field I four-squad, camp 1,016,600 
 
 Camp MacArthur Barracks and quarantine 
 
 camp 192,000 
 
 West Point, Miss., Payne 
 Field i four-squad, camp 812,100 
 
 Wichita Falls, Tex., Call 
 Field i four-squad, camp 1,016,600 
 
 Various fields Additions to barracks 340,000 
 
 Various fields Architectural services 150,000 
 
 Sundry projects 296,391 
 
 Total $47,863,228 
 
 16
 
 242 Wings of War 
 
 The advanced training school and field at 
 Issoudun in France and the great repair and assem- 
 bly shops at Romorantin and the whole physical 
 plant for the maintenance of the air service in 
 France required the assembling and forwarding of 
 a vast amount of material and machinery, and the 
 erection of many extensive buildings, hangars, 
 warehouses, shops, etc. In addition to the work 
 that was done by contract at home and abroad, it 
 ultimately required 49 construction squadrons, 23 
 construction companies, and 12 labor companies, 
 with a total of almost 13,600 officers and men to 
 do the work that was performed directly by the 
 supply division. Of these men about 6500 were 
 sent abroad. The assembly shops at Romorantin 
 were on such a scale that they could receive and 
 erect daily 100 'planes and forward them to the 
 front. The repair shops were of sufficient capacity 
 to handle all the repairs of injured and "crashed" 
 machines from the front and from the school. 
 The field shops at home eventually reached such 
 a magnitude that it is calculated that they were 
 capable of building 200 'planes a week. The 
 actual construction work in France, except for the 
 aviation school and the hangars that were origi- 
 nally provided or diverted from American fields 
 was attended to by the A. E. F.
 
 Training Fields and Camps 243 
 
 Three weeks after the building of the aviation 
 school at Issoudun was approved by the Air Prod. 
 Board all the materials for its erection were on 
 the docks in New York harbor accompanied by 
 two hundred mechanics and the necessary com- 
 plement of officers, and on September 15, 1917, 
 the school was ready for use, this work including 
 the building of seven miles of standard gauge rail- 
 way to connect the field with the railway trunk line. 
 
 To give some idea of the great amount of con- 
 struction work done at home it may be stated that 
 a typical single-unit flying field and school called 
 for 50 buildings of all kinds, occupying a space % 
 of a mile long by about 600 feet wide with graded 
 and macadamized roadways, railway tracks, water 
 and sewerage systems, lighting plants, etc., to say 
 nothing of the grading and draining of the field 
 proper. The standard plan was developed by 
 Albert Kahn, the Detroit architect, from the basic 
 scheme worked out by Cols. Waldon and Edgar. 
 
 An idea of the size and complexity of the tasks as- 
 signed to the Supply Division may be gained from a 
 recital of its divisions which were : executive, build- 
 ings and grounds Langley Field branch, finance, traf- 
 fic and storage, engine and 'plane maintenance, avia- 
 tion repair depots, oil and lubricating branch, ma- 
 terial branch, salvage, motor transport, real estate.
 
 244 Wings of War 
 
 All of these branches had an endless amount of 
 work to do and it always had to be done in a hurry. 
 The oil and lubricating branch, for instance, had 
 to conduct the development of suitable lubricants 
 for aviation engines, arrange for the planting of 
 one hundred thousand acres of castor beans by 
 1 8,000 farmers provide supplies of oils for the home 
 forces and the A. E. F., look after gasoline and 
 many other things. 
 
 One of its triumphs was the production of 4 ' Lib- 
 erty aero oil" without which the Liberty motor 
 would not have been properly lubricated. 
 
 The traffic and storage branch handled about 
 seventy-five thousand carloads of materials. 
 
 The Supply Division was the man behind the 
 gun for the aviator from the day he began his 
 training until he began to fight in France. On it 
 he depended for everything he used and consumed 
 to be always ready and exactly right. Its un- 
 known officers and obscure men worked with all the 
 ardor, zeal, and self-sacrifice of the more fortunate 
 fighters whose names were inscribed on the roll of 
 fame. There are records of mechanics and engi- 
 neers working four days and nights at a stretch in 
 the shops at the fields in order to keep the maxi- 
 mum number of machines and student aviators 
 in the air all the time.
 
 Partial View From the Air of the Vast American Air Service Assembly 
 
 Repair and Salvage Shops at Romorantin, France 
 
 U. S. Air Service Photo
 
 CHAPTER XXV 
 
 NAVAL AIRCRAFT PRODUCTION 
 
 WHILE army and navy aircraft production were 
 coordinated in a measure by the Aircraft Board 
 and by direct arrangements, and the develop- 
 ment and production of engines and some other 
 apparatus and the procurement of materials were 
 left to the army in whole or in part, the navy main- 
 tained throughout the war its own independent 
 aviation sections and directed development and 
 production to meet its own ideas and its peculiar 
 needs. Before 1916 the navy paid as much at- 
 tention to aircraft as was possible with the limited 
 appropriations available. The first appropriation 
 for Naval Aviation was made in 1916 and during 
 this year the Navy Department developed train- 
 ing planes and training facilities in addition to 
 adequate research and experimental facilities, in- 
 cluding the largest wind tunnel then in the world. 
 However, in 1917 it was clear that Naval Aviation 
 should concentrate itself upon anti-submarine op- 
 
 245
 
 246 Wings of War 
 
 erations and for this duty large patrol seaplanes 
 carrying depth charges were necessary. Steps 
 were taken promptly to obtain models for such 
 planes by development from existing types, but it 
 was not possible to fly these types until the Liberty 
 engine became available in the early autumn of 
 1917. The planes were ready as soon as the 
 engines were developed. The trials were success- 
 ful and the Navy Department entered upon a 
 program of production of two types of flying 
 boats, which program was adhered to. The un- 
 certainty as to program in the case of the navy did 
 not arise so much from a vast and varied foreign 
 experience as from the fact that naval aeronautics 
 had not advanced so rapidly during the European 
 war as military aeronautics, and the field was more 
 of an unknown or untried one. From 1912, when 
 aeronautical experimentation began in the navy, 
 to 1915, inclusive, only $55,000 had been set aside 
 for this work. In 1916, Congress appropriated 
 $1,000,000 for naval aviation, and its development 
 in any important way dates from then. At the 
 end of 1916, the total aircraft deliveries to the 
 navy consisted of about 95 seaplanes of experi- 
 mental and training types, "mainly prototypes of 
 the Curtiss N9 and R6, 3 kite balloons, and I non- 
 rigid dirigible." Thirty Curtiss N9's were de-
 
 Naval Aircraft Production 247 
 
 livered in the fall of 1916, and early in the spring 
 of 1917 64 more Ng's and 76 R6's were ordered. 
 
 Thanks to the wise forethought of Admiral 
 Taylor, chief constructor, the entry of the United 
 States into the war was preceded, in 1916, by the 
 ordering of a small number of machines of dif- 
 ferent types for the purpose of securing data 
 from which to choose the most suitable ones for 
 future training. These orders were placed with 
 the Curtiss Aeroplane and Motor Corporation, 
 the Burgess Company, the Sturtevant Airplane 
 Company, the Aeromarine 'Plane and Motor 
 Corporation, the Thomas-Morse Aircraft Com- 
 pany, the Standard Aircraft Corporation, the Boe- 
 ing Airplane Company, and the Gallaudet Air- 
 craft Corporation. Following these experimental 
 orders, contracts were given to the Burgess Com- 
 pany for 30 of the Curtiss Ng's (later increased to 
 360), to the Curtiss Company for 122 R6's, later 
 changed to Rg's, and to their respective companies 
 for 50 Boeings, 200 Aeromarines, and about 15 
 Curtiss F-boats, sportsman's type. 
 
 The problem of service 'planes, owing to lack of 
 knowledge of requirements and developments, was 
 not so easily disposed of. A board of officers 
 was sent abroad in September, 1917, to investi- 
 gate, and on its return, reported that because
 
 248 Wings of War 
 
 of foreign concentration on land 'planes there 
 was no satisfactory type of seaplane for coast 
 patrol and that it was desirable to develop Amer- 
 ican types, equipped with the Liberty motor. 
 Acting upon this information and knowing that it 
 had been decided to establish fifteen coastal air 
 stations abroad, the Joint Army and Navy Tech- 
 nical Board laid down a program that was accepted 
 in October, 1917. That it took six months before 
 it was possible to determine the service program 
 is both a commentary on our unpreparedness 
 and an explanation that disposes of accusations 
 of tardiness of action when the emergency arose. 
 Neither the navy nor the army could achieve 
 the impossible; neither could act intelligently nor 
 with important results before it could establish 
 an objective. 
 
 The program, having in view both initial re- 
 quirements and replacements for the stations 
 abroad and for home training was : 
 
 First: Eleven hundred and eighty-five HS-l 
 flying boats with Liberty engines. 
 
 Second: Two hundred and thirty-five H-l6 
 flying boats with Liberty engines. 
 
 Both of the service "boats" decided upon were 
 Curtiss models. 
 
 The controlling considerations in this program
 
 Naval Aircraft Production 249 
 
 were the fact that the Liberty engine was by that 
 time fully proved and a desire to avoid the dangers 
 of highly varied types. The two types chosen had 
 been demonstrated, and it was necessary to have 
 two, because there was need for both large and 
 small machines, especially as the smaller type 
 could be built more rapidly than the larger, and 
 shipping difficulties for the latter were anticipated. 
 The fighting objective of both types was the 
 German submarine, and for that purpose the 
 larger kind was favored, but the smaller was better 
 than none. The H-i6 was the larger and was an 
 improvement on the H-I2 which was a Curtiss 
 design adopted by the British navy, the Curtiss 
 company having early taken the lead in the devel- 
 opment of flying boats. In 1918 the H-i6 was 
 succeeded by the FsL which is slightly larger; and 
 the HS-i was followed by the HS2L. 
 
 The H-i6 is described as a tractor biplane, 
 carrying two Liberty engines. It has an over-all 
 length of 46 feet and an upper-wing spread of 
 95 feet. Stripped, it weighs 7400 pounds and with 
 ordinary equipment 10,900, while it has carried a 
 gross weight of 11,500 pounds. Its usual crew is 
 four men, its armament five Lewis machine guns 
 and two 23O-pound bombs. Its cruising limit is 
 nine hours light or six hours fully loaded. The
 
 250 Wings of War 
 
 has a wing spread of 103.75 feet, a bare weight 
 of 8250 pounds, a permissible load of 13,000, and 
 has actually flown with 13,600 pounds. Its arma- 
 ment is the same as that of the H-i6, with the ex- 
 ception that it carries four 23O-pound bombs and it 
 has a cruising limit at economical speed of eleven 
 hours, and with geared Liberty engines has attained 
 a speed of 100 miles an hour. The equipment of 
 both these boats includes radio apparatus, range 
 lights, signal lamps, intercommunicating telephone 
 sets, food, water, and a medicine chest. 
 
 The HSiL is about a third smaller in dimen- 
 sions than the FsL and is a single-engine coast- 
 patrol machine, the engine being a Liberty. Its 
 gross weight is 5900 pounds and its armament is 
 one machine gun and two i8o-pound bombs. 
 
 Contracts for these machines were awarded en- 
 tirely to existing plants except that in order to 
 augment the volume of production the navy erected 
 a large plant of its own at Philadelphia. 
 
 This program seemed large when adopted, but 
 two months later, on the advice of Admiral Sims, 
 the number of the twin-engine boats was increased 
 to 864, all to be delivered by the spring of 1919. 
 When this decision was made it was found that 
 480 of the total would have to come from some new 
 source, as about 400 was the outside capacity of
 
 Hulls of F-5-L Type Seaplanes. Curtis s Elmwood Plant, Buffalo 
 
 U. S. Air Service Photo 
 
 Final Assembly of Flying Boats at Curtiss Plant, Elmwood, Buffalo 
 U. S. Air Service Photo
 
 Naval Aircraft Production 251 
 
 the plants with which orders had already been 
 placed. It was not deemed wise to place complete 
 orders with new companies and on the other hand 
 the prospect of building and organizing a govern- 
 ment factory of adequate size was dismaying and 
 of doubtful wisdom. The problem was handled by 
 building an immense assembly plant as an exten- 
 sion of the naval aircraft factory, already erected, 
 and having the various parts built in many dif- 
 ferent established yacht-building, metal, and wood- 
 working plants that were quite capable of making 
 the parts though not qualified for executing the 
 whole job. It was the fabricated ship idea of 
 Hog Island applied to flying boats. 
 
 Quantity production of the service boats began 
 in April, 1918, thus running parallel with army 
 'plane production, with six HSL's and three H-i6's 
 a week. From that time on production rapidly 
 increased. 
 
 In June, 1918, the program was again expanded, 
 so that it called for additions of 700 FS'S, 300 
 HS2's, 300 F-boats, and 200 N9's a total of 1800. 
 Another hundred F-boats were added in Septem- 
 ber. In that month production reached its height, 
 twin Liberty engine boats coming out at the rate 
 of 13 a week, and single-engine (mostly Liberty) 
 at the rate of 38 a week. The former were made
 
 252 Wings of War 
 
 by the Naval Aircraft Factory, Curtiss Aeroplane 
 and Motor Co., Buffalo, Curtiss Engineering Cor- 
 poration, Garden City, L. I., N. Y., and the Cana- 
 dian Aeroplanes, Ltd., Toronto, Canada. The 
 latter were made by the Gallaudet Aircraft Cor- 
 poration, East Greenwich, R. L, the LWF En- 
 gineering Co., College Point, N. Y., Curtiss Aero- 
 plane and Motor Co., Buffalo, Standard Aircraft 
 Corporation, Elizabeth, N. J., and the Boeing Air- 
 plane Company, Seattle, Wash. In the same 
 month, training machines were being delivered at 
 the rate of 22 a week by the Burgess Company, 
 the Aeromarine Company, and the Curtiss Engi- 
 neering Corporation. 
 
 Before the armistice was signed, it was realized 
 that naval aircraft were being manufactured far 
 more rapidly than they could be utilized either at 
 home or abroad, and early in November the pro- 
 gram was curtailed by canceling 550 FS'S, 248 
 HS2's, and 300 training machines. After the 
 signing of the armistice, there was a further can- 
 cellation of 145 HS2's, 512 FS'S, and 100 school 
 machines. 
 
 Several new types of 'planes were developed by 
 or for the navy during 1918, with a view to meet- 
 ing the progress of naval aeronautics. The Aero- 
 marine company developed the Model 40 Flying
 
 Captain K. G. Pulliam, Jr., and His is-Meter, Decorated Nieuport Plane, 
 
 "The Jazbo" 
 
 American-Made Handley-Page Bomber with Single-Seater at Left
 
 Naval Aircraft Production 253 
 
 Boat and the Curtiss Engineering Corporation the 
 Model MF Flying Boat for training purposes, and 
 both were adopted by the navy. Several different 
 service machines were designed, built, and tried, 
 the most conspicuous being the NC-i, the Curtiss 
 model i8-T or Kirkham fighter, the N-i or Davis 
 gun carrier, and the HA or Liberty fighter. 
 
 The NC-i was built by the Curtiss Engineering 
 Corporation, under the direction of officers of the 
 Bureau of Construction and Repair. It is a bi- 
 plane with an upper- wing spread of 126 feet, and 
 an over-all length of a trifle more than 68 feet. Its 
 weight with full load was 22,000 pounds; stripped, 
 it weighed 13,200 pounds. It was driven by three 
 Liberty motors and had a hull of unique design, 
 which rather resembled a large pontoon. This 
 machine made a flight at Rockaway Beach, L. 
 I., on November 27, 1918, with 51 persons on 
 board, thereby establishing the world's record for 
 airplane passenger carrying. Later four engines 
 were installed in the NC-i, three tractor and one 
 pusher. Due to this change the light weight be- 
 came 16,000 Ibs., and the total weight 28,000 Ibs. 
 The NC-i was followed by three other NC's of like 
 type, and it was the NC-4 that won the high dis- 
 tinction of being the first aircraft to leap the 
 Atlantic.
 
 254 Wings of War 
 
 The Curtiss i8-T is a two-place tri-plane land 
 machine, designed as a guard for the heavy naval 
 bombing machines along the French coast. It is 
 driven by a Curtiss K-I2 engine and has a speed 
 of 162 miles an hour, which makes it the fastest 
 'plane ever built up to this time. 
 
 The N-i was designed to carry a Davis Q-pound- 
 er non-recoil gun, and is of the pusher type that 
 is, has the propeller behind instead of in front, as 
 is the arrangement with the ordinary or tractor 
 type, in order to put the gun at the nose. As it 
 was afterwards found possible to mount the Davis 
 gun on the HS-2 flying boat, less attention has been 
 paid to the N-i than it would have had otherwise. 
 
 The Liberty fighter is a single pontoon seaplane, 
 designed to meet enemy aircraft. It is a two-seater 
 and carries four machine guns and has attained 
 the remarkable speed, for a seaplane, of 127 miles 
 an hour. 
 
 One dirigible balloon was built for the navy in 
 1916 by the Connecticut Aircraft Company, and 
 that was about the extent of the navy's equipment 
 with the buoyant aircraft when we entered the 
 war. In the January before the war was declared 
 a single-engine, tractor, training dirigible of 
 80,000 feet capacity was designed by the Bur- 
 eau of Construction and Repair, and in March
 
 Naval Aircraft Production 255 
 
 orders were placed for 16, the contracts for the 
 envelopes being taken by the Goodyear Tire & 
 Rubber Company, the B. F. Goodrich Company 
 of Akron, the United States Rubber Company of 
 Akron, Ohio, and the Connecticut Aircraft Company. 
 The obstacles in the way of rapid progress at first 
 have been set forth elsewhere, but in general they 
 were those of a new industry which must be de- 
 veloped in an industrial hothouse. The first vessel 
 of this type was tested in July, 1917, and the rest 
 were delivered by the spring of 1918. Their suc- 
 cess in coast patrol work was such that it was de- 
 cided in the spring of 1918 to build 10 twin-engine 
 dirigibles of 175,000 cubic feet capacity, this num- 
 ber being later increased to 30. These airships 
 were known as the " C " class and designed by the 
 Bureau of Construction and Repair. The first of 
 these larger vessels was ready in October but the 
 armistice came before the others were done, and 
 it was decided to reduce the number to be com- 
 pleted to 15. 
 
 The kite balloon program provided for 600 bal- 
 loons, and 50 of the Caquot M type were delivered 
 in the first part of 1918. Later the Caquot R 
 type was taken up and finally an improved M 
 type. With the coming of peace the balloon pro- 
 gram was reduced one half.
 
 256 Wings of War 
 
 In connection with the use of balloons the navy 
 had much the same problems as the army with 
 special variations to meet nautical conditions. 
 Some of these problems were solved with the army 
 and some separately. The development of winches 
 and cables for handling the balloons from vessels 
 were serious and difficult matters. The N. C. L. 
 Engineering Corporation of Providence, R. I., de- 
 veloped the gasoline engine winch or windlass 
 along the "surge" type, following foreign practice, 
 which avoids a compression of the cable by winding 
 it in a single layer in grooves on one or more drums, 
 which take all the pull, the stored part of the cable 
 being wound around other drums under slight 
 tension. The Lidgerwood Company of New York 
 modified its cargo vessel steam winch for balloon 
 handling and towing in an ingenious manner, but 
 it was finally found that this class of winches was 
 not adapted to handling balloons at great heights, 
 especially when the telephone cables were inside 
 the holding cables, owing to the crushing com- 
 pression. Seventy-five of the NCL gasoline 
 winches were ordered and quantity production 
 was attained in the spring of 1918. Another vari- 
 ation of the winches was the use of steam power 
 with the "surge" drum; and still another, the 
 "surge" drum with electrical power; the latter
 
 Naval Aircraft Production 257 
 
 being specially adapted to capital ships. The man- 
 ufacture of the balloon cable and its problems have 
 been mentioned elsewhere, they being problems 
 common to the army and navy. 
 
 The navy shared the dope and fabric tasks and 
 problems with the army, but in a large measure 
 faced and solved its own spruce problem. At first 
 it had intended to rely on the army for all its 
 spruce, as the latter had found it necessary to make 
 arrangements on a mammoth scale for the pro- 
 curement of the fine Sitka spruce of the north- 
 western Pacific States. The troubles the army 
 encountered, owing to labor and other obstacles 
 that presented themselves, prompted the navy to 
 consider other sources, the chief of which turned 
 out to be the New England spruce forests, and it 
 was agreed that the cultivation of this field of 
 supply should be left to the navy. By May, 1918, 
 about seventy mills were turning out New England 
 white spruce at the rate of a million feet a month, 
 by which time the northwestern supply was so 
 abundant that the navy had more lumber than it 
 needed. Some of the surplus stock was sold to 
 the British Government. In July, however, the 
 army began to run short of spruce for struts and 
 the navy surplus proved to be very opportune for 
 some plants. There was much disfavor for New
 
 258 Wings of War 
 
 England spruce because of its small pin-knots and 
 short lengths, but necessity enforced its use and 
 specifications were altered to meet its requirements. 
 Later when waterproof glue and laminated con- 
 struction were developed, it came into considerable 
 favor and there was a steady preferential demand 
 for a considerable quantity of it. The navy supple- 
 mented its New England supply with small quanti- 
 ties of Sitka spruce from sources overlooked by the 
 army, which were shipped east by the Canadian 
 Pacific railway and sold to the New England lum- 
 ber mills having navy spruce contracts. 
 
 The rapid erection and prompt operation of the 
 government naval aircraft factory is worthy of 
 special notice. The reasons which prompted the 
 decision to erect such a plant have already been 
 noted. On August 6, 1917, a contract was let for 
 a plant that would have a capacity of 1000 train- 
 ing seaplanes a year. The factory proper was 400 
 feet by 400 of permanent construction and there 
 were some auxiliary buildings. Work on the first 
 boat in this plant began on October I2th and the 
 building was entirely completed on November 
 28th. When it was decided to meet the require- 
 ments of the greatly enlarged program adopted in 
 December, 1917, by having the parts of the sea- 
 planes made elsewhere and assembled at the naval
 
 Naval Aircraft Production 259 
 
 factory, two other great buildings, 350' x 400' and 
 680' x 200', besides large auxiliary buildings had to 
 be erected. This great assembly plant was fed 
 with seaplane parts by the Victor Talking Machine 
 Company, which had almost abandoned its ordi- 
 nary work to turn its workers and equipment 
 to the government's work, seven yacht yards, 
 two small aircraft factories, by a number of furni- 
 ture factories and automobile body and sheet 
 metal products factories. Over 7000 persons were 
 employed on the naval work in these private plants, 
 in addition to 3643 in the naval aircraft factory, 
 itself. The groups of cooperating factories were 
 managed as parts of the naval factory that 
 happened to be long distances away, instead of 
 right alongside the executive offices ; thus welding 
 the whole enterprise into a single unit. The as- 
 sembling and training of the workers was a great 
 problem in itself, not more than 25 of the 3700 
 in the central plant ever having had previous 
 experience in aircraft-making. The objective of 
 the factory and assembling plant was the making 
 of 830 twin-engine "boats," and the necessary 
 spares, which would cost $23,000,000. On De- 
 cember 31, 1918, the production amounted to 183 
 of these vessels, 50 sets of spare parts, and 4 
 experimental machines; not to mention experi-
 
 260 Wings of War 
 
 mental work, individual fittings, and parts for 
 service machines. 
 
 It is noteworthy that in these naval records and 
 accounts of army production of aircraft and acces- 
 sories it is found that quantity production is rarely 
 mentioned before the early spring of 1918. From 
 this, as well as from the like experiences of other 
 production for war purposes, it is fair to generalize 
 that it took the United States one year to mobilize 
 industrially and, all things considered, that was a 
 wonderful achievement. That is to say, in a gen- 
 eral way, that a year elapsed from the declaration 
 of war until the manufacturing resources of the 
 United States began to be felt in the special ma- 
 chinery of war, except in the cases of those indus- 
 tries and plants that had already been mobilized 
 to meet the demands of the European nations, pre- 
 vious to our entry into the war. It also took about 
 a year to get ready to send troops to Europe in 
 large numbers. These facts may well cause serious 
 reflection as to what would have happened to 
 us had the war been solely between the United 
 States and Germany. We had a year to get ready 
 this time, after war was declared. Even then, it 
 would have been a year more before we were ready 
 to exert the full strength that our industrial devel- 
 opment represented.
 
 Partial View of the Great A. E. F. Air Service Training School at Issoudun, 
 
 France 
 
 U. S. Air Service Photo 
 
 Tuning up a Spad in a Field Hangar at the Front 
 
 U. S. Air Service Photo
 
 CHAPTER XXVI 
 "LYNCHING THE AIRCRAFTERS" 
 
 No branch of the American war production 
 effort has been subjected to so much persistent, 
 widespread and relentless criticism as that of air- 
 craft production, although the fact is that the 
 production of aircraft and all of its accessories is 
 really one of the most wonderful achievements of 
 the war and it abounds with records of great tasks 
 greatly done. Why then, it may be asked, was it 
 singled out for such a flood of persistent and, often, 
 virulent criticism? The answer is fourfold. 
 
 First, aircraft design and production were so 
 comparatively new in this country that there was 
 room for wide divergence of opinion and judgment 
 as to the best course to follow in regard to many 
 features of the undertaking and ample opportunity 
 for anyone to set himself up as authority. 
 
 Second, publicity that was flamboyant and exag- 
 gerated on the one hand and insufficient on the 
 other hand. 
 
 261
 
 262 Wings of War 
 
 Third, underestimates by the aircraft managers 
 and the manufacturers of the time it would take to 
 get American aircraft plants of all sorts into large 
 production. 
 
 Fourth, lack of a thoroughly coordinated and 
 efficiently functioning organization of the air serv- 
 ice as a whole. 
 
 The first answer requires no elaboration here as 
 it is really dealt with throughout this work. 
 
 The mistakes of publicity arose partly from over- 
 confidence and partly from the fact that so little 
 of a definite nature could be given out, under the 
 regulations of military secrecy, that generalities 
 had to be resorted to, and the rest left to the imag- 
 ination of the eager writers who were fascinated 
 by the magnitude of the American air effort and the 
 results that would follow if it were realized. On 
 the other hand, looking back now it would appear 
 that much of the data regarding the procurement 
 of materials and the production of 'planes, engines, 
 and the numerous accessories might well have been 
 given to the public and thus familiarized it with 
 the enormous difficulties the aircraft managers 
 faced. The result of the ill-advised publicity was 
 to raise false hopes of early achievement on a scale 
 of great magnitude while not informing the people 
 of the extent and variety of what was actually
 
 " Lynching the Aircrafters " 263 
 
 being done, with a correspondingly great disap- 
 pointment when it was learned that those hopes 
 were not to be realized, though the actual achieve- 
 ment was of surpassing brilliance and solidity. 
 
 While the faulty publicity was only partly the 
 error of the aircraft organization, it must be 
 charged with responsibility for underestimates of 
 the periods of production. For reasons which have 
 been made plain elsewhere the aircraft managers 
 erred in this respect, partly because of an abiding 
 optimism, which was essential to the successful 
 prosecution of their work, and partly because they 
 allowed themselves to be deceived by the sanguine 
 time-estimates of manufacturers. 
 
 Now that the situation is better understood, 
 that the public is beginning to understand that the 
 aircraft producers did a great work greatly, and 
 time has confirmed their judgment and their con- 
 fidence in the ability of American manufacturers 
 successfully to apply quantity production methods 
 to aircraft-making, there is little need to dwell at 
 length on the bitter criticisms of the aircraft mana- 
 gers and producers. Neither is more than a pass- 
 ing reference required to the various investigations 
 which followed each other throughout the war and 
 culminated in the Senate Military Affairs Commit- 
 tee investigation and the executive investigation
 
 264 Wings of War 
 
 conducted by Chas. E. Hughes in association with 
 the Department of Justice. The passage of time, 
 the record of the facts, the full and accurate pub- 
 licity that the termination of the war has made 
 possible, and the realization that these investiga- 
 tions could not have the impartiality resulting from 
 the personal detachment which only a lapse of 
 time makes possible, have made them largely 
 unimportant. At the time they loomed large and 
 threatened to discredit permanently a vast field 
 of American war effort and all who were associated 
 with it, and most certainly had the effect, along 
 with some good, of cruelly harassing and seriously 
 retarding progress. 
 
 The defective organization was inherent in the 
 American military system and was largely the 
 inevitable result of leaving in a minor place a 
 department of military preparation that was soon 
 to surpass in magnitude and complexity the most 
 extravagant of pre-war forecasts, and trying to 
 supplement it with a largely impotent but com- 
 plication-adding Aircraft Board. Time pressed so 
 urgently that there was no leisure to conceive or 
 perfect an adequate organization at first. The 
 aircraft production managers had all they could do 
 in the stress of preparation for production on an 
 enormous scale without diverting thought and en-
 
 " Lynching the Aircraf ters " 265 
 
 ergy to a campaign for the attainment of a proper 
 place and system for the air service as a whole in 
 the government's organization for war, much as 
 they realized the need of a different scheme. 
 
 One good result of criticism and investigations 
 was a shifting of the place of the air service in the 
 general military scheme and of a simplification of 
 the internal organization. Changes in the latter 
 became necessary to restore public confidence, and 
 also to restore the morale of the organization 
 which had suffered so much from criticism. Thus 
 it came about that eventually, some months before 
 the termination of the war, the whole air service 
 was withdrawn from the Signal Corps, and placed 
 under John D. Ryan as Assistant Secretary of 
 War, and under him was the Bureau of Aircraft 
 Production on the one hand and the Division of 
 Military Aeronautics on the other hand. Major 
 General W. L. Kenly was placed in charge of 
 military aeronautics which had to do with the 
 fighting air service and W. C. Potter, who was 
 Colonel Deed's chief of the equipment division of 
 the Signal Corps, was made chief of production. 
 At the same time all matters relating to aircraft 
 were divorced from the Signal Corps. In this 
 manner the air service attained an independence 
 and degree of authority that it had not hitherto
 
 266 Wings of War 
 
 enjoyed. Mr. Ryan inspired great respect and 
 confidence, and supplied a centralized headship 
 that had not been possible under the old system. 
 He found, however, that the production or equip- 
 ment work was well organized and efficient, and 
 so far as it was concerned it continued about 
 as it was under a different name and authority. 
 Mr. Ryan has frequently stated that he came 
 into the organization too late to be credited with 
 the results achieved in creation and production. 
 He modestly claims for himself merely the filling 
 of a harmonizing function, which the progress of 
 events had made necessary. 
 
 In a public address in New York City not long 
 since, Mr. Ryan said : 
 
 "Mr. Toastmaster, ladies and gentlemen, public 
 speaking is not in my line, but I- would be a poor 
 sort of a fellow if I couldn't say a word to you men 
 assembled here to-night, I would be a poor fellow 
 if I couldn't say in appreciation of what you have 
 done for the country, and done for the Cause, that 
 we have won so gloriously, done for me in the 
 short time that I had to do with aircraft produc- 
 tion that probably no one has come out of the 
 war with as much credit for what somebody else 
 did as I have. 
 
 "I was called into aircraft production at a
 
 "Lynching the Aircrafters" 267 
 
 time, as Mr. Marshall says, when there was a 
 great deal of discussion, a great deal of criticism, 
 and a great deal of blame, and I say to you 
 to-night in all earnestness, most of it was totally 
 and entirely undeserved. 
 
 "Aircraft production had to start at the begin- 
 ning. It had to find a way from nothing, to meet 
 the demands of the American people, and be brought 
 to a point that was beyond all reason. People 
 talked of clouds of airplanes, of tens of thousands of 
 sparrows, and it was just as impossible to realize 
 that dream as it was to realize any kind of a dream. 
 Aircraft had to be built slowly, carefully, they had 
 to be built to conserve, first, the lives of these gal- 
 lant boys who took these ships in the air. They had 
 to be" made sure, every wrinkle, every crinkle, every 
 thing that could be a menace to the life of these 
 boys had to be taken out of them, if it was pos- 
 sible, before they were sent to fight across the line, 
 and they had to fight across the line. 
 
 "The work that was done before me made it 
 comparatively easy for me to win a good deal of 
 praise, as I say, that I was not entitled to. The 
 work of my predecessors, the work of the aircraft 
 manufacturers of the United States was a thing 
 that, when I got into it and studied it, was amazing 
 to me in its competency, and all it lacked was just
 
 268 Wings of War 
 
 time enough and just some organization to center 
 it, to drive it in the direction, and to finish it. 
 
 "The manufacturers of this country, with singu- 
 lar devotion to the country, with great patriotism, 
 and with the greatest earnestness that I have ever 
 seen in any body of men, had built an organization 
 for the manufacture of aircraft that certainly has 
 never been equalled in the world, in the time in 
 which it has been done. 
 
 "The brains that were in the aircraft organiza- 
 tion at the time that I took charge of it had been 
 well-directed. There were some things that might 
 have been better done. There are things always 
 that might have been better done, but in the main, 
 in the mass, the work was well laid down, it was 
 under way, and the manufacturers of this country 
 who were making aircraft were doing a wonderful 
 job, as far back as last May. 
 
 "The greatest effort necessary to build aircraft, 
 as you gentlemen know, to start the building of 
 aircraft, was in the building of the engines, and is 
 there anybody here to-night who doubts that the 
 accomplishment of the American manufacturers of 
 engines was one of the greatest accomplishments 
 in the war, one of the greatest things done in the 
 war? When the war ended there wasn't a nation 
 on our side of the war and I am sure there wasn't
 
 " Lynching the Aircraf ters " 269 
 
 one on the other who would not take every en- 
 gine we could build for them of the types we were 
 building, there was not a single nation in the war 
 that did not want more of what we were making 
 than we could build for them. 
 
 "And we did not do so badly. From the time 
 we began, we built more engines, and we built more 
 'planes, month for month, from the time we began, 
 than any nation in the war built from the time it 
 began. We had more engines ready, and we had 
 more 'planes ready, month by month, from the 
 time we commenced, than any nation in the war 
 had month by month from the time it commenced. 
 
 "But the American manufacturers of aircraft, 
 the American engineers, with their ingenuity, their 
 brains, their patriotic devotion, the tremendous 
 work they put into it, were building so well and 
 even so fast that the day the armistice was declared 
 there were 686 American 'planes at the port of 
 embarkation that could not be loaded. That was 
 not the fault of the shipbuilders. Mr. Marshall 
 gave us more credit than we were entitled to. But 
 the reason for it was that while we were building 
 a good many 'planes, a great many other people 
 were building other things that General Pershing 
 and the people on the other side wanted very 
 badly, and they were taking trucks and ordnance
 
 270 Wings of War 
 
 and other things that they needed very badly, and 
 leaving aeroplanes for the last few days, but the 
 fact remains and we have it to our credit that we 
 had more 'planes ready for them than they were 
 ready to take. It was a great adventure, and we 
 are all proud of it." 
 
 Since the signing of the armistice the Aircraft 
 Board has been abolished and the air service has 
 been reorganized again with Maj. Gen. Chas. T. 
 Menoher, who commanded the 42d Division in 
 France, as Director of the Air Service, which is 
 divided into four groups, namely, Supply, Infor- 
 mation, Training and Operations, and Adminis- 
 trative. The group of Training and Operations 
 really succeeds the division of Military Aero- 
 nautics of the Ryan regime; Brig. Gen. Wm. 
 Mitchell therein succeeds Gen. Kenly. Col. W. E. 
 Gillmore is at the head of Supply group, which 
 takes the place of the Bureau of Aircraft Produc- 
 tion; Maj. H. M. Hickam at the head of Informa- 
 tion and Col. W. F. Pierson at the head of the 
 Administrative staff. Gen. Menoher's executive 
 officer relating him to the rest of the organization 
 is Col. M. F. Davis and there is also an advisory 
 board made up of Col. W. S. Kilner, Col. A. L. 
 Fuller, Col. H. C. Pratt, Lt. Col. G. B. Hunter, 
 Lt. Col. B. Q. Jones, and Major C. R. Cameron.
 
 "Lynching the Aircrafters" 271 
 
 In the end, the men of the equipment division 
 of the Signal Corps who were so aspersed and even 
 humiliated were fully vindicated officially. They 
 needed no vindication in American business and 
 manufacturing circles. As the public gets the 
 right perspective and a proper understanding of 
 the multitude of almost insuperable difficulties 
 under which they tirelessly, patriotically, and 
 thanklessly struggled, it too will accord honor 
 where it was wont to give censure.
 
 CHAPTER XXVII 
 
 REVIEW AND PROSPECT 
 
 Now that it is possible to survey the whole field 
 of America's industrial production for war pur- 
 poses it is plain that the country did much better 
 than it seemed to be doing during the war when 
 the emergency was so pressing, celerity so vital, 
 and each mistake, or delay, or error of judgment 
 loomed so large. In consequence of the basic 
 national fault of not preparing for what was com- 
 ing, it was necessary to try to do everything in an 
 incredibly short period of time. There was little 
 time for deliberation. Plans and their realization 
 had to be almost simultaneous. Often realiza- 
 tion was far advanced before the plan was revealed 
 to be faulty. Marshal Foch's admonition, "Do 
 not delay half a minute!" rang in everyone's ears. 
 Almost everyone who was in touch with the vast 
 effort for production was aware of confusion, per- 
 sonal incompetence, ill-advised courses, and the 
 dilatoriness of official routine. The accumulation 
 
 272
 
 Review and Prospect 273 
 
 of this discouraging personal experience resulted in 
 a widespread pessimism which tended to obscure 
 the fact that whether by muddling or by clear- 
 headedness, thanks to a prodigious output of en- 
 ergy, the great enterprise was moving ahead all the 
 time with increasing momentum. 
 
 Assistant Secretary of War Benedict Crowell has 
 recently published a voluminous report on the 
 production of munitions during the war, which 
 though it does not have the value of an impartial 
 review does enable one to get an adequate impres- 
 sion of the colossal extent of the munitions work 
 and compare relative degrees of success and prog- 
 ress of the different departments of the effort. It 
 shows clearly that aircraft production was at least 
 as well and as swiftly done as the other parts of 
 the mountainous job. Reviewing what was accom- 
 plished, some of the outstanding features might be 
 mentioned as follows: 
 
 Prompt provision of training fields, quarters, 
 general equipment, schools, and supplies for 
 190,000 men. 
 
 Rapid procurement of training 'planes and en- 
 gines on the requisite scale, 1406 'planes and 
 1905 engines being produced in 1917, production 
 beginning as early as June on the 'planes and in 
 July on the engines ; that is to say within two or 
 
 18
 
 274 Wings of War 
 
 three months after the declaration of war; and 
 being adequate for the training requirements of a 
 force of 190,000 men within a year. The total of 
 training 'planes for the first year of the war with 
 only nine months of real production was 3428. 
 This compares favorably with the total British pro- 
 duction of 2040 for the calendar year 1915, after 
 giving the British producers a starting period from 
 August i to December 31,1914. Our engine produc- 
 tion for the same period was probably 25 per cent, 
 greater than the corresponding British production. 
 The designing and production of the Liberty en- 
 gine is now conceded on all sides to have been a 
 brilliant and praiseworthy effort. It is now per- 
 ceived that taking all things into consideration, to 
 design and manufacture such a nice, complex, and 
 powerful mechanism, far in advance of continental 
 development with respect to amount of power, 
 within one year was an extraordinary achievement. 
 The best promise for a transplanted foreign engine 
 was 500 machines in that period, whereas there 
 were actually produced noo Liberties. The de- 
 cision to produce the Liberty engine, widely crit- 
 icized at the time, as a fundamental mistake, 
 turned out to be one of the most judicious decisions 
 of the war. It put us aerially on the battle line 
 with American equipment.
 
 Review and Prospect 275 
 
 The production of battle 'planes, pivoted on en- 
 gineering and military advice and judgment, and 
 was slower in getting under way than that of train- 
 ing 'planes and engines and the Liberty motor, but 
 when the gates of production were opened progress 
 was exceedingly rapid, and the rate of output of 
 them was near 20,000 a year when hostilities 
 ceased, which again compares very favorably with 
 a total British production of 14,400 in the third 
 year of the British effort. Our actual home pro- 
 duction of 'planes of all kinds during ten months 
 of 1918 was 1 1,815, an d had the armistice not been 
 signed in that year, would have been 15,000. 
 
 The progress made in balloon production was 
 more than satisfactory. 
 
 The record of the designing and manufacturing 
 of all the accessories for airplanes and balloons is 
 one of the brightest chapters in American indus- 
 trial history. 
 
 The discovery of economical methods of pro- 
 ducing helium gas was a brilliant and momentous 
 feat, which will have a profound effect on the 
 future of lighter-than-air craft. 
 
 The adaptation of cotton fabric to airplane wing- 
 covers was a lifeline for the Allies as well as for 
 ourselves. 
 
 The production of spruce in sufficient quantity
 
 276 Wings of War 
 
 to keep going all the French, British, and Italian 
 aircraft factories, as well as our own, was a 
 marvelous feat. 
 
 The production of dope was similarly important 
 and meritorious. 
 
 The ample provision of machine guns of both 
 the fixed and flexible type for aerial use reflected 
 prompt and wise decision and swift production. 
 
 The immense material equipment forwarded to 
 France and England for the aviation supplies and 
 training camps there as well as for the manufac- 
 ture of airplanes for the American army by French 
 manufacturers is extremely noteworthy. Hardly 
 less important to the Allies were the 18,000 Amer- 
 ican mechanics who were sent to their assistance. 
 
 The actual shipment of a considerable surplus 
 of Liberty engines to the Allies within eighteen 
 months of our entry into the war was an excep- 
 tional achievement. 
 
 While we were toiling and moiling at aircraft 
 production at home we kept the shops and factories 
 of the Allies going with our endless supplies in 
 itself an achievement of the first rank. 
 
 The building up in about fifteen months from 
 almost nothing of a great executive and admin- 
 istrative organization and an aircraft industry of 
 more than 300 plants and more than 200,000
 
 o 
 en 
 
 "8 
 
 ex 
 o. 
 
 '3 
 
 a" 
 
 W 
 
 a 
 2 o 
 
 V 
 
 I 
 
 -o 
 
 3 
 CO* 
 
 2 
 
 OJ
 
 Review and Prospect 277 
 
 workers that had already achieved an engine 
 production greater than that of all the Allies and 
 that was soon to have realized a corresponding 
 rank in 'plane production, is now seen to have 
 been a supernormal deed. Viewed in the per- 
 spective it seems hard to understand why the 
 ability and success with which the work was 
 being prosecuted were not understood when we 
 were in the midst of it. 
 
 It reflects no aspersions on other fields of war 
 production to say that the most lauded and appre- 
 ciated of them did not do better than the aircraft 
 producers. A few not invidious comparisons may 
 be made. 
 
 The war had lasted a year before the first or- 
 dered ship was delivered to the Shipping Board. 
 The first steel ship on order from an Atlantic 
 Coast yard was not delivered until September, 
 1918. 
 
 Only 80 tanks were completed when the ar- 
 mistice was signed and only 16 had been floated 
 overseas. 
 
 Up to May I, 1918, only 85 heavy Browning 
 machine guns had been turned out. 
 
 Practically no hand or rifle grenades that were 
 satisfactory were delivered from American facto- 
 ries until about the end of hostilities. Before
 
 278 Wings of War 
 
 November n, 1918, we had shipped to France only 
 181 75-millimeter guns and only 114 155-mms. 
 
 Our total shipments of artillery of all kinds were 
 815 units and the total production 2034. 
 
 This may be compared with a total production 
 of 16,000 Liberty motors and more than 30,000 
 air engines of all kinds. Exclusive of the 1800 
 Liberty engines shipped over-seas in 'planes, 6210 
 were floated uninstalled. 
 
 The total shipments of combat 'planes to France 
 were about 2000 as against 815 guns. 
 
 Of trench mortars we had completed only about 
 1500 at the signing of the armistice. We produced 
 only 101 anti-aircraft guns, counting only complete 
 units. 
 
 These facts are cited merely to show that even 
 with unlimited financial resources, great manufac- 
 turing capacity, splendid executive ability and 
 with speed of production as the supreme objective, 
 miracles cannot be accomplished. Except in 
 respect to service rifles and machine guns, it re- 
 quired a year and a half to get into the full 
 volume of production that the magnitude of the 
 war required. In fact, we found that we could 
 not adequately equip an army of millions from 
 our own factories before the spring of 1919, that 
 is, two years after the war began. Had not
 
 Review and Prospect 279 
 
 France and England, but especially France, been 
 able to furnish the artillery and much of the other 
 equipment of our first two million men, we would 
 have contributed almost nothing to the effective 
 land forces of the Allies before the spring of 1919. 
 The offset of this deplorable fact is that we were 
 able to supply the Allies with vast quantities of 
 war materials for their factories and food for their 
 armies and civilian populations. While we were 
 taking the punishment in the form of two years 
 of delay for our incredible folly of not preparing 
 for war we were able to contribute decisively to 
 keeping our friends in the field until we could 
 come up. The time it took us to get ready 
 shows clearly how helpless we would have been 
 even in a defensive war against Germany or any 
 other first-class military power if the navy could 
 not hold the seas. 
 
 In profiting by the expensive lesson of the recent 
 war, our authorities must give great attention to 
 aircraft of all sorts. In a future war we shall be 
 largely dependent upon the degree of progress that 
 the civil utilization of aircraft shall make in the 
 meantime. To promote civilian interest in aero- 
 nautics and to keep alive some of the aircraft or- 
 ganizations that were created during the war, 
 liberal government appropriations are necessary.
 
 280 Wings of War 
 
 Moreover an adequate engineering organization 
 must be maintained and to maintain it there must 
 be ample funds available for experimentation with 
 and the purchase of new types. By being in the 
 market for the purchase of a considerable number 
 of machines yearly the government will not only 
 keep aircraft manufacturing alive and vigorous but 
 it will make opportunities for private aeronautical 
 engineers and engineering companies to continue 
 their researches. There is thus a certain need for a 
 large government engineering establishment. As 
 this establishment and private concerns bring out 
 new types that are approved and adopted, draw- 
 ings and blueprints can be made, dies can be pre- 
 pared, and all the preliminaries of manufacture 
 made ready against the day of need. When these 
 are ready, quantity manufacture, through the 
 conversion of plants, is but a matter of a compara- 
 tively short time. But beyond this, it will be 
 necessary to maintain constantly on hand an 
 amount of up-to-date equipment far in excess of 
 the numbers of the aviation military personnel. 
 This means constant renewal and scrapping to 
 keep abreast of the progress of the art. So, an 
 adequate program of aerial defense will provide a 
 considerable volume of business for a few manu- 
 facturers even in peace times.
 
 Review and Prospect 281 
 
 The greater the civilian interest in and use of air- 
 craft the smaller the government establishment 
 may be; so, it would seem to be wise economy for 
 the air service to use its aviators and all its 
 facilities and resources to stimulate the demand for 
 aircraft. With thousands of civilian flyers and ma- 
 chines there will be a sufficient demand to maintain 
 many factories; and the flyers, the machines, and 
 the plants will be ready in an emergency. The 
 air service must therefore proceed on a much 
 larger scale with its plans for landing fields all over 
 the country, with the mapping of air routes, with 
 the encouragement of the use of airplanes in the 
 postal service, where a good beginning has already 
 been made, in forest patrol, in coast patrol, in 
 meteorology, with the encouragement of aeronau- 
 tical clubs and associations. All this work could 
 probably best be done by creating an independent 
 air service that would be both military and civil, 
 though there are not lacking arguments against 
 centralization of control. 
 
 The end of the war found us potentially the 
 world's leader in the quantity production of air- 
 craft. Most of the machines used by all the nations 
 will soon be obsolete, so that we have only to 
 adopt and maintain an aeronautical policy corre- 
 sponding to the size and resources of the country
 
 282 Wings of War 
 
 from now on to take and maintain the first place 
 in the air. The "jump" in the next war will be 
 enjoyed by the combatant with the superior air 
 service. It is conceivable that other branches of 
 the military service may never even get an oppor- 
 tunity for action. The war may be over and de- 
 cided in the air before land and naval forces can be 
 utilized. Have we learned anything from this war 
 or shall we again lapse into indifference and again 
 expect our leaders and builders to accomplish the 
 impossible and then blame them instead of our- 
 selves as we did in the great war that is just now 
 receding into history?
 
 INDEX 
 
 Advisory Commission, Council 
 of National Defense, 16 
 
 Aero-Marine Co., 19 
 
 Aeromarine plants, New Jer- 
 sey, 134 
 
 Aeronautics, National Advi- 
 sory Committee on, 14 
 
 Air battle, description of, by 
 Col. Brereton, 203, 204 
 
 Aircraft Board: 
 Atkins, Lieut. Commander, 
 
 Arthur K., 29 
 Deeds, Col. E. A., 28 
 Howe, Richard, 29 
 Irwin, Captain Noble E., 29 
 Montgomery, Robert L., 28 
 Squier, Brig. Gen. Geo. O., 28 
 Taylor, Admiral D. W., 29 
 Thayer, L. R., 29 
 
 Aircraft factory, naval, gov- 
 ernment, 258-260 
 
 Aircraft, machine guns for, 
 189-196 
 
 Aircraft manufacture, centrali- 
 zation of responsibility, 132 
 
 Aircraft, naval, manufacturers: 
 Aeromarine 'Plane & Motor 
 
 Corporation, 247 
 Boeing Airplane Co., 247 
 Burgess Co., 247 
 Curtiss Aeroplane & Motor 
 
 Corporation, 247 
 Gallaudet Aircraft Corpora- 
 tion, 247 
 
 Standard Aircraft Corpora- 
 tion, 247 
 
 Sturtevant Airplane Co., 247 
 
 Thomas-Morse Aircraft Co., 
 
 247 
 Aircraft production, 1-6 
 
 American, general plans, 61, 
 62 
 
 Congressional appropri- 
 ations, 24 
 
 Criticism, 261-271 
 
 French cooperation re- 
 stricted, 56 
 
 Naval, 245-260 
 
 Naval, appropriations, 245, 
 
 246 
 Aircraft Production Board, 23 
 
 Coffin, Howard E., chair- 
 man, 23 
 
 Deeds, Col. Edward A., 23 
 
 Montgomery, Robert L., 23 
 
 Squier, Brig. Gen. George O., 
 23 
 
 Taylor, Admiral D. W., 23 
 
 Waldon, Sidney D., 23 
 Aircraft program: 
 
 Army and Navy Technical 
 Board, 34-38 
 
 Estimates, 26, 27, 28 
 Aircraft standardization, 
 
 American and European, 42, 
 
 43 
 
 Airplane, birthland of, 7 
 Airplane cloth, grades, 184, 
 
 .185 
 Airplane, Martin bomber, 
 
 tests, 169, 170 
 
 Airplane patents, royalties, 20 
 Airplane production: 
 
 American, history of, 7-9 
 
 283
 
 284 
 
 Index 
 
 Airplane production Cont'd 
 
 England, 7 
 
 France, 7 
 
 Germany, 7 
 Airplane production results, 
 
 171-173 
 Airplanes: 
 
 Congressional appropriation, 
 
 17 
 
 De Haviland 4*5, shipments, 
 
 72 
 Development of types, 135, 
 
 136 
 Fighting, 12 
 
 Apparatus, 12 
 Airplanes in service at front, 
 
 data, 172 
 Airplanes: 
 
 Service, selection of types, 
 
 144-150 
 Single-seater pursuit, 158, 
 
 159 
 Speed of, compared, 157, 
 
 158 
 Sprucewood for, problem, 
 
 174-180 
 
 Two-seater fighter, 159 
 Airplane training, 39 
 Air Reduction Co., 232, 233 
 Air Service: 
 American, French codper- 
 
 ation, 51-53 
 German, comparison, 73 
 Allies, production, aid to, by 
 
 America (footnote), 55 
 American airplane production, 
 
 history, 7-9 
 American Handley-Page, data, 
 
 165 
 American motor, standardized, 
 
 68, 100 
 American Steel & Wire Co., 
 
 230 
 Army and Navy Technical 
 
 Board, aircraft program, 34- 
 
 3. 8 
 Aviation, military: 
 
 Chief function, 2 1 0-2 1 4 
 Classified 
 
 Bombardment, 199-204 
 
 Observation, 199, 204 
 Pursuit, 199, 204 
 Aviation section, U. S. Signal 
 
 Corps, personnel, 8 
 Aviation situation in United 
 States, 1916 , 12, 13 
 
 B 
 
 Balloon manufacturers: 
 
 Connecticut Aircraft Co., 
 
 227 
 Firestone Tire & Rubber Co., 
 
 227 
 
 Goodrich Co., 227 
 Goodyear Co., 227 
 Knabenshue Manufacturing 
 
 Co., 227 
 
 United States Rubber Co., 
 227 
 
 Balloons and accessories, data, 
 236 
 
 Balloons, demolition, fragmen- 
 tation, and incendiary, 216, 
 217 
 
 Biplane, Caproni, American 
 made, records, 167 
 
 Boiling Commission: 
 Boiling, Col. R. C., 37 
 Childs, Lieut., U. S. N., 38 
 Clarke, Capt., 37 
 Gorrell, Edgar S., 37 
 Hughes, Herbert, 38 
 Marmon, Howard, 38 
 Westervelt, Commander, U. 
 S. N., 38 
 
 Boiling Commission, foreign 
 co6peration, 51, 52 
 
 Boiling Commission, recom- 
 mendations, 60 
 
 Bombs, airplane, 215 
 
 Brereton, Lieut. Col. Lewis H., 
 statement, 74, 75, 199, 200 
 
 British Air Ministry, contract, 
 164 
 
 Brock, Arthur, Jr., aerial 
 photography, 211 
 
 Bureau of Standards, codper- 
 ation, 183
 
 Index 
 
 285 
 
 Canadian Aeroplanes, Ltd., 
 252 
 
 Camera, machine-gun, use, 
 223 
 
 Cameron, Maj. C. R., 270 
 
 Caquot, Captain, balloon in- 
 ventor, 226, 227 
 
 Christofferson Co., 19 
 
 Clarke, Capt. V. E., report, 
 26 
 
 Clarke, Lieut. Col. Virginius 
 E., 15 
 
 Coffin, Howard E., 16 
 
 Colpitts, E. H., engineer, 207 
 
 Corrnack, Brig. Gen. J. D., 
 British War Mission, re- 
 marks by, 112, 113 
 
 Cotton fabric, development of, 
 181-186 
 
 Craft, Edward B., engineer, 
 207 
 Article by, 207-210 
 
 Crane, H. M., engineer, 82 
 
 Crowell, Benedict, Assistant 
 Secretary of War, report, 
 273-282 
 
 Culver, Col. C. C., 206 
 
 Cunningham, James, Sons & 
 Co., windlass production, 
 230 
 
 Cunninghair., Maj. A. A., 
 statement by, 149, 150 
 
 Curtiss Airplane Co., pro- 
 duction, 41 
 
 Curtiss Co., 9 
 
 Curtiss engine, 0X5, 122 
 
 d'Annunzio, Captain, 1 66 
 Davis, Col. M. P., 270 
 Day ton- Wright Co., pro- 
 duction, 41 
 
 Deeds, Col. Edward A. : 
 Aeroplane accessories and 
 
 materials, 174-176 
 Aircraft production, re- 
 sponsibility, 138-143 
 
 American motor standard- 
 ized, 100 
 
 Apparatus, technical, devel- 
 oping, 30 
 
 Chief of Equipment Divi- 
 sion, Signal Corps, 23, 28 
 
 Criticism and vindication, 
 111-113 
 
 Engineers selected by, 77 
 
 Head of army aircraft pro- 
 duction, 29 
 
 Industrial executive officer, 
 Signal Corps, 23 
 
 Liberty motor, conception 
 of, by, 66-74 
 
 Liberty motor cylinders, 
 117-120 
 
 Liberty motor manufacture, 
 difficulties, 85-87 
 
 Liberty motors, development 
 
 of, 97-101 
 De Haviland 4*5: 
 
 Characteristics of, 150, 151 
 
 Production of , 151 
 Disque, Gen. Brice P., 177 
 Dope, fabric, manufacturing 
 
 problem, 186-188 
 Duesenberg Motors Corpora- 
 tion, 10 
 
 Eastman Kodak Co., aerial 
 
 photography, 212 
 Edgar, Col. C. C., 239 
 Emmons, Lieut. Harold H., 
 
 32 
 
 Engine production, 94, 95 
 Engineers: 
 
 Burgess, Starling, 10 
 
 Clark, Capt. V. E., 10 
 
 Curtiss, Glen, 10 
 
 Day, Charles, 10 
 
 Hall, E.J., II 
 
 Hunsaker, J. C., 10 
 
 Loening, Grover C., 10 
 
 Martin, C. M., 10 
 
 Thomas, B. D., 10 
 
 Vincent, J. G., 10 
 
 Vought, C. M., 10
 
 286 
 
 Index 
 
 Engineers Cont'd 
 Willard, Daniel, 10 
 Wright, Orville, 10 
 
 Engineers and manufacturers, 
 
 committee: 
 Beall and Roberts, 95 
 Chrysler, Walter, 95 
 Hall, Lieut. Col. E. J., 95 
 Heaslet, James G., 95 
 Leland, Henry M., 95 
 Wills, C. Harold, 95 
 
 Engine factory, sites for, 126 
 
 Engines: 
 American type, advantage, 
 
 7i 
 
 De Haviland 4, 49 
 
 Development and produc- 
 tion of, 122-131 
 
 Distribution of, 130 
 
 Liberty, contracts and de- 
 liveries, 129 
 
 Liberty motor, 49 
 
 Rolls-Royce, production of, 
 64 
 
 Types of, comparison, 127, 
 
 128 
 Engle Aircraft Co., production, 
 
 41 
 
 Equipment, personal, avi- 
 ators', 215, 219-224 
 
 Fekete, Mr., engineer, 82 
 Fergusson, David, engineer, 
 
 82 
 Fiat Plant, Schenectady, N. 
 
 Y., cooperation, 128 
 Fisher Body Corporation, pro- 
 duction, 41 
 Fletcher, Peter, 182 
 Flying boat: 
 
 Model 40, 252 
 
 Model MF., 253 
 Flying fields, 240-243 
 
 Construction, cost, 240, 241 
 Flying machine, heavier-than- 
 air, 7 
 
 Invented in America, 7 
 
 Foch, Marshal, admonition, 
 272 
 
 Ford Motor Co., 97 
 
 Forests Products Laboratory, 
 Madison, Wis., 179 
 
 Foulois, Brig. Gen. B. D., 15 
 
 Fowler Aircraft Co., produc- 
 tion, 41 
 
 Fuller, Col. A. L., Army Air 
 Service, article, 234, 235, 
 270 
 
 G 
 
 Gallaudet Co., 19 
 
 Garros, Roland, French avi- 
 ator, 191 
 
 Gas: 
 
 Helium, non-inflammable, 
 
 231 
 Hydrogen, production, 231 
 
 Gas production, Norton pro- 
 cess, 232, 233 
 
 G. E. M. Engineering Co., 
 aerial photography, 212 
 
 General Vehicle Co., 9 
 
 Gillmore, Col. W. .,270 
 
 Gnome engines, production, 
 48 
 
 Grand Rapids Airplane Co., 
 164 
 
 Guillot, M. Georges, 45, 46 
 
 H 
 
 Hall, E. J., engineer, 77 
 
 Hall-Scott Co., 10, it 
 Production, 41 
 
 Hamilton, Alex. K., 46 
 
 Hawley, Lieut. Frank M., 46 
 
 Heinrich Co., 19 
 
 Herschell-Spillman Co., co- 
 operation, 128 
 
 Hickham, Maj. H. M., 270 
 
 Hispano-Suiza engines, 47, 48 
 Contracts for, 124 
 
 Horner, Leonard S., 31 
 
 Hunter, Lieut. Col., G. B., 
 270
 
 Index 
 
 287 
 
 Hutton, Col. W. H. H., 15, 
 32 
 
 Issoudun training field, 
 France, 242, 243 
 
 Jewett, Dr. Frank B., engineer, 
 207 
 
 Johnson, Claude, director 
 Rolls-Royce Co., 125, 126 
 
 Joint Army and Navy Techni- 
 cal Board program, 248- 
 
 255 
 
 Jones, Col. E. Lester, 239 
 Jones, Lieut. Col. B. Q., 270 
 
 Kahn, Albert, architect, 243 
 Kenley, Maj. Gen. W. L., 265 
 Kilner, Col. W. S., 270 
 King, Charles B., Signal Corps, 
 
 128 
 Kite balloons, Caquot types, 
 
 255 
 Knox Motors, 10 
 
 Lawrence engines, production, 
 
 48 
 Leland, "Uncle" Henry, 92, 
 
 93 
 Le Rhone engines, production, 
 
 45. 4 6 
 
 Lewis, Col. Isaac N., machine- 
 gun inventor, 193 
 Liberty engine: 
 
 Adopted by British Air 
 Ministry, 113 
 
 Birth of, 76-84 
 
 Origin of, 63 
 
 Tests, 89 
 Liberty engine, parts for, made 
 
 by: 
 
 Aluminum Castings Co., 88 
 
 Burd High Compression 
 
 Ring Co., 88 
 
 Cadillac Motor Car Co., 88 
 Delco Co., 89 
 General Aluminum & Brass 
 
 Manufacturing Co., 88, 
 
 89 
 
 Gibson Co., 89 
 Hall-Scott Motor Car Co., 
 
 88 
 Hess- Bright Manufacturing 
 
 Co., 88 
 
 L. O. Gordon Manufactur- 
 ing Co., 88 
 Packard Co., 88, 89 
 Park Drop Forge Co., 88 
 Rich Tool Co., 88 
 Zenith Carburetor Co., 89 
 Liberty motor: 
 American standard, 97 
 Description of parts, 98- 
 
 100 
 
 Total production, 109, no 
 Liberty motor contractors: 
 Ford Motor Co., 91 
 General Motors Corporation 
 
 (Buick and Cadillac), 91 
 Leland, H. M., 92, 93 
 Lincoln Motor Co., 91 
 Nordyke & Marmon, 91 
 Packard Motor Car Co., 91 
 Trego Motors Corporation, 
 
 9 
 
 Liberty motor production, 
 102-115 
 
 Incidents of, 116-121 
 Liberty motors: 
 
 Contracts, 91 
 
 First, making, 85-91 
 Lidgerwood Co., 256 
 Linde Air Products Co., 232, 
 
 233 
 Loyal Legion of Loggers and 
 
 Lumbermen, 177 
 LWF Engineering Co., 252 
 
 M 
 
 Machine guns, shipments, 193, 
 194
 
 288 
 
 Machines : 
 
 Night-bombing, types, 162- 
 
 168 
 Scout, for training, 159, 160 
 
 Machine tools, manufacture, 
 American methods, 69-71 
 
 Marne salient, photographic 
 data, 20 1, 202 
 
 Martin, Glenn L. designer, 
 167-170 
 
 Masks, oxygen, 222 
 
 Maynard, Lieut. B. W., trans- 
 continental airplane flight, 
 114 
 
 McCauley, Capt. Theodore C., 
 non-stop record flight by, 
 114 
 
 McKeen Motor Car Co., wind- 
 lass manufacturer, 230 
 
 Menoher, Maj. Gen. Charles 
 T., 270 
 
 Milling, Capt. De Witt, 15 
 
 Minton, J. P., inventor, 207 
 
 Mitchell, Brig. Gen. William, 
 15. 203, 270 
 
 Mixter, George W., 31 
 
 Moore, Frank C., 46 
 
 Mullins Co., 164 
 
 N 
 
 Naval Aircraft Factory, 252 
 NCL Engineering Corporation 
 
 windlass manufacture, 256 
 New York Aero Co., 19 
 Nordyke-Marmon Co., pro- 
 duction, 41 
 
 Northcliffe, Lord, British Mis- 
 sion, codperative engine 
 manufacture, 125, 126 
 
 O 
 
 Oxygen apparatus, production, 
 222, 223 
 
 Pacific Co., 19 
 
 Packard Motor Car Co., 10 
 
 Patents and royalties, 141-143 
 
 Pershing, Gen. John J., rec- 
 ommendations of, 60 
 
 Photography : 
 Aerial, 210^214 
 
 Accessories, shipments, 
 
 213 
 
 Aviation, German offensive 
 checked by, 201, 202 
 
 Fierce-Arrow Co., 10 
 
 Pierson, Col. W. F., 270 
 
 Pigeon Frazer Co., 19 
 
 'Planes, bombing, battle, 202, 
 203 
 
 Pomilio brothers, 'plane build- 
 ers, 161 
 
 Potter, W. C., 265 
 
 Pratt, Col. H. C., 270 
 
 Pyrotechnics, aerial, 215-219 
 
 R 
 
 Radio telephone, 197-210 
 Radio telephony, article, by 
 
 Edward B. Craft, 207-210 
 Read, Commander, U. S. N., 
 
 aerial crossing of Atlantic, 
 
 114 
 
 Remington Co., production, 41 
 Review and prospect, 272- 
 
 282 
 
 Rinehart, Howard M., 145 
 Roebling, Chas. A., & Sons 
 
 Co., 230 
 
 Rubay & Co., production, 41 
 Ryan, John D., Assistant 
 
 Secretary of War: 
 Address, 266-270 
 Statement by, 131 
 
 Schoonmaker, J. M., Jr., 
 
 engineer, 80 
 Shepler, Harry L., 31 
 Signal Corps vindicated, 271 
 Sims, Admiral W. S., 250 
 Speny gyroscope, 217 
 Springfield Aircraft Co., pro- 
 duction, 41
 
 Index 
 
 289 
 
 Squier, Maj. Gen. George O., 
 
 15 
 
 Standard Aerocraft Co., pro- 
 duction, 41 
 
 St. Louis Car Co., production, 
 
 41 
 
 Stratton, Dr. S. W., 81 
 Sturtevant Co., 10 
 
 Production, 41 
 
 Thomas- Morse Co., 10 
 Thompson, Melville W., 31 
 Training fields, camps, and 
 
 supply, 238-243 
 Traub, Gen. Peter A., 72, 73 
 Tulasne, Maj., French Mili- 
 tary Commission, 143 
 
 U 
 
 Union Iron Works, 10 
 
 Union Switch & Signal Co., 
 
 production, 45, 46 
 U. S. Bureau of Standards, 
 
 aerial photography, 212 
 U. S. Signal Corps, aerial 
 
 photography, 212 
 
 "Very" pistol, 218 
 
 Victor Talking Machine Co., 
 
 259 
 
 Vincent, J. G., 31 
 Engineer, 77 
 
 W 
 
 Waldon, Col. S. D., 15, 16, 239 
 Western Electric Co., radio 
 
 telephone, 206, 207 
 White, Capt. E. P., non-stop 
 
 flight, 114 
 
 White, D. McCall, engineer, 82 
 White, J. G., Co., machinery, 
 
 tools, etc., 54, 55 
 Willys-Morrow Co., pro- 
 duction, 40 
 
 Wisconsin Engine Co., 10 
 Wright Brothers, inventors, 7 
 Wright-Martin Co., 9 
 Production, 41 
 
 Zimmerschied, K. M., metal- 
 lurgist, 80
 
 "The Maintenance 
 of Peace" 
 
 The Foundations of Domestic and International 
 
 Peace as Deduced from a Study of the 
 
 History of the Nations 
 
 By 
 
 S. C. Vestal 
 
 Lieutenant-Colonel, Coast Artillery Corps, U. S. Army. 
 
 Formerly Colonel 339th Field Artillery, 
 
 National Army 
 
 This book is a study of the factors that 
 disturb domestic and international peace. 
 These factors are political and can be settled 
 only by political agencies never by courts or 
 arbitration, nor by indifference and neglect, 
 nor by conferring war powers upon advisory 
 bodies not possessing authority to support 
 armaments by taxation. International peace 
 may be preserved by the power of the 
 majority of mankind as domestic peace is 
 preserved by the power of the majority in a 
 nation. The author shows how this desir- 
 able end has been and may be achieved. 
 
 G. P. Putnam's Sons 
 
 New York London
 
 LEADERSHIP 
 
 By 
 
 ARTHUR HARRISON MILLER 
 
 Major, Coast Artillery Corps, U. S. Army; Office of 
 the Chief of Staff, War Plans Division 
 
 With a Foreword by 
 EDWARD L. MUNSON 
 
 Colonel, U. S. Army; Chief of the Morale Branch; 
 War Plans Division, Office of the Chief of Staff 
 
 A Study and Discussion of the Qualities 
 Most to be Desired in an Officer, and of 
 the General Phases of Leadership which 
 have a Direct Bearing on the Attaining 
 of High Morale and the Successful 
 Management of Men 
 
 "Leadership" is included in the Official 
 List of Publications recommended by 
 the War Department for study and refer- 
 ence by all students of Reserve Officers 
 Training Corps Units in Universities, 
 Colleges, Military Academies, and Schools 
 
 G. P. Putnam's Sons 
 
 New York London
 
 UG Knappen - Wings of war. 
 633 
 
 MAY 9 1951 
 
 University of California 
 
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