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Hans Ohain

Hans Ohain


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Hans Ohain was born in Dessau, Germany on 14th December, 1911. After studying at the University of Gottingen he was employed by Ernst Heinkel, the German aircraft builder.

In 1939 Ohain developed the HE 178. With its centrifugal-flow turbojet engine, the plane made its first flight on 27th August, 1939. Ohain followed this success by building the HeS 8A which was first flown on 2nd April, 1941 and the Heinkel He 162 that appeared in 1945.

After the Second World War Ohain emigrated to the United States where he worked on jet aircraft for the US Air Force. Hans Ohain died in Florida on 13th March, 1998.


Hans von Ohain Wiki, Biography, Net Worth, Age, Family, Facts and More

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BIOGRAPHY

Hans von Ohain is a well known Inventor. Hans was born on December 14, 1911 in Dessau, Germany..Hans is one of the famous and trending celeb who is popular for being a Inventor. As of 2018 Hans von Ohain is 86 years (age at death) years old. Hans von Ohain is a member of famous Inventor list.

Wikifamouspeople has ranked Hans von Ohain as of the popular celebs list. Hans von Ohain is also listed along with people born on 14-Dec-11. One of the precious celeb listed in Inventor list.

Nothing much is known about Hans Education Background & Childhood. We will update you soon.

Details
Name Hans von Ohain
Age (as of 2018) 86 years (age at death)
Profession Inventor
Birth Date 14-Dec-11
Birth Place Dessau, Germany
Nationality Dessau

Hans von Ohain Net Worth

Hans primary income source is Inventor. Currently We don’t have enough information about his family, relationships,childhood etc. We will update soon.

Estimated Net Worth in 2019: $100K-$1M (Approx.)

Hans Age, Height & Weight

Hans body measurements, Height and Weight are not Known yet but we will update soon.

Family & Relations

Not Much is known about Hans family and Relationships. All information about his private life is concealed. We will update you soon.

Facts

  • Hans von Ohain age is 86 years (age at death). as of 2018
  • Hans birthday is on 14-Dec-11.
  • Zodiac sign: Sagittarius.

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Hans Ohain - History

Before World War II, in 1939, jet engines primarily existed in labs. The end of the war, however, illustrated that jet engines, with their great power and compactness, were at the forefront of aviation development.

A young German physicist, Hans von Ohain, worked for Ernst Heinkel, specializing in advanced engines, to develop the world's first jet plane, the experimental Heinkel He 178. It first flew on August 27, 1939.

Building on this advancement, German engine designer Anselm Franz developed an engine suitable for use in a jet fighter. This airplane, the Me 262, was built by Messerschmitt. Though the only jet fighter to fly in combat during World War II, the Me 262 spent a significant amount of time on the ground due to its high consumption of fuel. It was often described as a “sitting duck for Allied attacks.” Meanwhile, in England, Frank Whittle invented a jet engine completely on his own. The British thus developed a successful engine for another early jet fighter—the Gloster Meteor. Britain used it for homeland defense but, due to lack of speed, it was not used to combat over Germany.

The British shared Whittle's technology with the U.S., allowing General Electric (GE) to build jet engines for America's first jet fighter, the Bell XP-59. The British continued to develop new jet engines from Whittle's designs, with Rolls-Royce initiating work on the Nene engine during 1944. The company sold Nenes to the Soviets—a Soviet version of the engine, in fact, powered the MiG-15 jet fighter that later fought U.S. fighters and bombers during the Korean War.

The 1945 surrender of Germany revealed substantial wartime discoveries and inventions. General Electric and Pratt & Whitney, another American engine-builder, added German lessons to those of Whittle and other British designers. Early jet engines, such as those of the Me 262, gulped fuel rapidly. Thus, an initial challenge was posed: to build an engine that could provide high thrust with less fuel consumption.

Pratt & Whitney resolved this dilemma in 1948 by combining two engines into one. The engine included two compressors each rotated independently, the inner one giving high compression for good performance. Each compressor drew power from its own turbine hence there were two turbines, one behind the other. This approach led to the J-57 engine. Commercial airliners—the Boeing 707, the Douglas DC-8—flew with it. One of the prominent postwar engines, it entered service with the U.S. Air Force in 1953.

The Man Behind The Engine

Hans von Ohain of Germany was the designer of the first operational jet engine, though credit for the invention of the jet engine went to Great Britain's Frank Whittle. Whittle, who registered a patent for the turbojet engine in 1930, received that recognition but did not perform a flight test until 1941. Ohain was born December 14, 1911, in Dessau, Germany. While pursuing doctorate work at the University of Gottingen, he forumulated his theory of jet propulsion in 1933. After receiving his degree in 1935, he became a junior assistant to Robert Wichard Pohl, director of the university's Physical Institute.

Granted a patent for his turbojet engine in 1936, Ohain joined the Heinkel Company in Rostock, Germany. By 1937 he had built a factory-tested demonstration engine and, by 1939, a fully operational jet aircraft, the He 178. Soon after, Ohain directed the construction of the He S.3B, the first fully operational centrifugal-flow turbojet engine. This engine was installed in the He 178 airplane, which made the world's first jet-powered aircraft flight on August 27, 1939. Ohain developed an improved engine, the He S.8A, which was first flown on April 2, 1941. This engine design, however, was less efficient than one designed by Anselm Franz, which powered the Me 262, the first operational jet fighter aircraft.

Ohain came to the United States in 1947 and became a research scientist at Wright-Patterson Air Force Base,the Aerospace Research Laboratories, Wright's Aero Propulsion Laboratory, and the University of Dayton Research Institute.


Development Of The Jet Engine

In the mid-1930s while working as a Junior Assistant, he partnered with an automotive engineer (Max Hahn) to turn his prototype into a workable engine. Hahn worked at a garage that regularly serviced Ohain’s automobile.

The first attempt at making the model engine failed because of technical issues. Its main problem was its instability.

The design called for the fuel to burn in flame cans which were actually on the outer parts of the engine.

However, at times, the fuel would move from the flame cans and burn in other parts of the engine causing it to overheat. Still, Ohain did not give up.

Robert Pohl also believed in Ohain’s work and design concept.

To assist Ohain, he sought out Ernst Heinkel, a German Aircraft Designer and known member of the Nazi party.

Heinkel and Von Hain celebrating the first flight of the He 178 jet. Image: Flickr.com


The Converging Paths of Whittle and von Ohain

No one who witnessed the first flight by a jet aircraft had any idea of the revolution that the jet engine would bring. The secret flight in Germany of the Heinkel He-178 on Aug. 27, 1939, led to revolutions in aviation, warfare, transportation, politics, and the world economy.

A functioning jet engine was realized at about the same time by two independent inventors, British Frank Whittle and German Hans Pabst von Ohain. They could not have differed more in personality.

Whittle, an extremely proficient Royal Air Force pilot, was quick tempered and acerbic, and he did not suffer fools gladly.

Von Ohain, an academic, was much younger, only recently graduated from his university, and possessed of a warm, engaging personality enhanced by a natural diffidence.

They approached the problem of creating a jet engine differently as well. Whittle totally immersed himself in the hands-on work, subcontracting out only those elements that were too complex for him to build. He was constantly applying theory to, and deriving theory from, the engine as it progressed.

In contrast, von Ohain was not a mechanic and taught himself to be an engineer only after he had received his doctorate. He hired a skilled mechanic to create the original model engine and then worked within the framework of a large aircraft company to bring the engine to fruition.

Whittle was totally unaware of von Ohain’s work. Von Ohain was conscious of other efforts to patent a jet engine, but did not draw upon any of the available knowledge. His preferred operating style was to work out his own ideas first, then see what others had done.

The two men had three things in common: initial governmental failure to recognize the immense potential of their experiments totally inadequate rewards for their great invention and extravagant exploitation of their efforts by others.

Out of the Midlands

Frank Whittle was born in Coventry, England, in 1907 to a working class family. His father was an inventive mechanic who, despite his lack of a technical education, provided Frank with the incentive to excel technically. Young Whittle fulfilled a dream by joining the Royal Air Force as an apprentice at the age of 16. His goal was to become a pilot.

Hugh Trenchard, Marshal of the Royal Air Force, made many important contributions to the RAF, but none more so than his concept of apprentice training. Trenchard insisted that his enlisted and noncommissioned personnel have a sound education. Then he wanted his average RAF airman to have three years’ training as an apprentice before entering service as a mechanic or other skilled worker.

Trenchard believed that only educated and well-trained men could become professional airmen. To sweeten the pot, he further stipulated the top five apprentices in each class could become cadets and receive flight training.

Whittle was rejected on his first attempt to join the Boy Apprentice Training program for poor physical fitness, but followed a diet and exercise regime that allowed him to pass his next attempt. He reported for training in September 1923. It was the best investment in personnel the RAF would ever make.

Whittle performed well enough to be selected for pilot training and was a natural pilot. He graduated second in his class despite some crashes, nonregulation low flying, and a few disciplinary problems.

Whittle earned his high class ranking by excelling in his studies—in spite of his reluctance to engage in team sports. He was troubled by a sharp temper that would affect his dealings with others for much of his life.

At the RAF College at Cranwell, he wrote a groundbreaking paper, “Future Developments in Aircraft Design.” It postulated that speeds of 500 mph or more could only be achieved in the stratosphere and that a new form of propulsion—rocket or gas turbine—would be required.

On graduation, Pilot Officer Whittle was posted to No. 111 Squadron at Hornchurch, flying the Armstrong-Whitworth Siskin IIIA. In September 1929, he was posted to the famed Central Flying School at Wittering to learn how to become an instructor pilot.

His distress at leaving the atmosphere of an operational squadron was offset by additional free time. More important, he met others who believed in his idea of a gas turbine. One of these was Flight Officer W.E.P. Johnson, who had been a patent agent in civil life. Whittle settled on a new type of gas turbine, one using neither a piston engine nor a propeller.

Johnson smoothed the way for Whittle to present his ideas to the British Air Ministry. There, Whittle ran into the bureaucratic opposition that would delay the development of his engine by five critical years. The agonizing process would also do much to wreck his health.

Under the guidance of Alan A. Griffith, the Air Ministry’s position was that the materials needed to endure the heat and stress implicit in a gas turbine were not available. The ministry also felt that the gas turbine would require too much fuel to be practical.

Unfortunately for both Whittle and the United Kingdom, Griffith had a basic conflict of interest, favored piston engines, and had a proprietary interest in the subject.

Whittle persisted, and a patent was granted in 1930.

In 1936, Whittle and two former RAF pilots, J.C.B. Tinling and Rolf Dudley-Williams formed a new company, Power Jets Limited, to act on behalf of Whittle and to raise money for developing his invention. Whittle, scrupulous about any possible conflict of interest, informed the government, which allowed him to proceed on the basis that it not interfere with his normal duties.

On Paper, Anything Is Possible

On paper, Whittle seemed to have solved the problem of jet propulsion. In practice, he was challenging the limits of everything known about compressors, turbines, metals at high temperatures, and the physics of compressed air flow.

Whittle learned how to build a jet engine by building one.

Power Jets always lacked money, but Whittle’s persistence and frugality kept it alive through many lean years.

The critical initial experiments in combustion did not begin until October 1936. Some preliminary testing of Whittle’s engine took place in March 1937, the same month that Griffith furnished an official Air Ministry report that essentially declared the jet engine noncompetitive with conventional power plants. The “WU” (for Whittle Unit) was fired for the first time on April 12, 1937.

The initial firing of the jet engine was a near disaster. The engine ran away, reaching a then-incredible 8,000 revolutions per minute before Whittle was able to shut it down.

There followed a series of nerve-racking trials, each one fraught with the possibility of a catastrophic explosion. Whittle’s life was often in danger as he stayed with the engine, trying to control it—and sometimes succeeding.

The combination of financial and developmental problems undermined Whittle’s health. He was now on the RAF special duty list, able to devote his full time to the redesign and manufacture of his engine.

Testing on the new engine began in April 1938. Results were mixed. For a while, sustained runs of more than an hour were being made, but the engine eventually broke down and was redesigned and rebuilt.

It was not until the summer of 1939 that the Whittle engine began running at sustained speeds of up to 16,000 RPM.

The declaration of war on Germany on Sept. 3, 1939, at last induced the British Air Ministry to pursue the advantages of an aircraft engine that weighed less, cost less to manufacture, and could use almost any sort of fuel.

Power Jets was given a contract to deliver a flight-worthy engine, and on Feb. 3, 1940, Gloster Aircraft Co. was given a contract for two prototype jets. The aircraft were designated the E.28/39.

Meanwhile, Back in Germany …

Hans-Joachim Pabst von Ohain grew up in an atmosphere of noble affluence. His father, Wolf Pabst von Ohain, was a military officer who married twice into the same wealthy family. His first wife died, and after a suitable interval he married her sister Katherina Louise, who gave birth to Hans in 1911.

Hans von Ohain’s childhood was idyllic, with plenty of vacations and no lack of funds. In 1930, he entered the Georg August University at Göttingen, a prestigious technical school. There he studied aerodynamics and thermodynamics under world famous instructors.

Von Ohain experimented briefly with gliding but stopped when participation required him to be a Nazi. His interest in aircraft propulsion was kindled in 1931, when he took a flight in a Junkers Ju-52 and found that the noise and vibration ruined the beauty of flight.

He decided to make flying as beautiful as gliding was to him—and to do it as simply as possible. In 1933, he began pondering jet propulsion. His first concepts involved no moving parts whatsoever, but he soon shifted to the idea of using a compressor and a turbine.

Von Ohain continued working on his ideas, even as he completed seven years of doctoral work in four years. He received a patent for his jet engine concept on Nov. 10, 1935—nine days after receiving his doctorate in physics.

He also had the good fortune to work with Max Hahn, a mechanic with a knack for building things of metal. He took von Ohain’s drawings, analyzed them, and agreed to build a model of the device.

While the test model ran only with assistance from an electric motor, its compressor did pump, its combustor burned, and the turbine rotated. This indicated that von Ohain was on the right track.

Building the engine was beyond his resources, so von Ohain sought out financing and backing. One of his mentors wrote a letter of introduction for him to Ernst Heinkel, who immediately agreed to meet in March 1936.

Heinkel was an important manufacturer, supplying a wide range of aircraft to the Luftwaffe. He wanted to manufacture engines, but knew his company would not be allowed the time or resources to develop piston engines, as his arch rival Junkers had done. Thus the idea of a revolutionary new engine was attractive.

Heinkel already had Walter and Siegfried Günter working for him on a rocket plane, the He-176. Heinkel knew that the Günters would be able to design an experimental airframe to test von Ohain’s jet engine.

Von Ohain’s position was now better than Whittle’s had ever been. Hahn was hired with him, and a special workshop was set aside for his use.

In addition he had access to Heinkel’s equipment, engineering team, and finances. Von Ohain and Hahn began their work at Heinkel in April 1936, unaware that Frank Whittle was immersed in building his first test engine.

The Germans sidestepped the enormous problems Whittle was encountering with combustion by designing their test engine to run on hydrogen gas. It was placed in a test rig in March 1937 and ran successfully. A few months later, design work began on the airframe, the Heinkel He-178.

Heinkel was pleased by von Ohain’s success and demanded a flight-worthy engine as soon as possible. Much needed to be done to make a jet engine that would function on conventional fuel. Two prototype engines were built.

The first prototype, the HeS 3A, was capable of producing 992 pounds of static thrust by March 1939. This was tested in the air, slung beneath the fuselage of a Heinkel He-118.

The second prototype engine, the HeS 3B, was modified by the flight-test experience and was available for installation in the brand-new He-178 in August 1939.

In an eerie forecast of a future hazard to jet aircraft, flight testing of the He-178 was delayed when a bird was sucked into the air intake during taxi tests. The engine was cleaned and repaired, and on the morning of Aug. 27, 1939, Flugkapitän Erich Warsitz made history with the He-178.

It was the first turbojet aircraft ever to fly.

This was a remarkable run for von Ohain, who had gone from a vague concept to a successful flight in about three years. Unfortunately for von Ohain, in the future, things would not go quite so well for his engine.

Back in Great Britain …

Squadron Leader Frank Whittle continued at his same furious pace. He was in a constant series of disagreements with the Air Ministry, which was determined to take his work and turn it over to other companies for development.

Whittle had developed a functioning jet engine on a ludicrously small budget—less than $60,000—but lacked the confidence of the Air Ministry.

Whittle worked closely with Gloster in creating the E.28/39, which (except for its tricycle landing gear) happened to have the same low-wing monoplane configuration used by the He-178. After preliminary taxi tests, Gloster’s chief test pilot, P.E.G. Sayer, made the first flight on May 15, 1941.

The combination of stress, overwork, and lack of appreciation continued to sap Whittle’s health. It did not help that he smoked and drank too much.

Once the British government realized how important his work was, it elected to provide information on the jet engine to Rover, Rolls Royce, Metropolitan-Vickers, and de Havilland, literally putting them in business on the back of Frank Whittle.

The information also was shared with the United States, where General Electric was tasked with developing the engine. Whittle gladly came over to help.

There followed a long series of business events that saw Power Jets nationalized—at great economic and personal cost to Whittle.

Promoted to air commodore, Whittle soldiered on. He received a grant of £100,000 from the Royal Commission on Awards for Inventors in May 1948, a pittance in light of the billion dollar industry that developed from his invention.

In July 1948, he was knighted. Sir Frank became sick on a lecture tour in the United States and retired from the RAF on the basis of ill health in August 1948.

Whittle continued to consult and lecture as his health permitted and eventually immigrated to the United States in 1976, where he became a research professor at the US Naval Academy in Annapolis, Md. Honors were heaped on him over the years until his death on Aug. 9, 1996.

Operation Paper Clip

Von Ohain continued his developmental work for Heinkel, and his new engine, the HeS 8A, powered the world’s first jet fighter, the Heinkel He-280. There were difficulties with this engine—its thrust was low and its diameter was too large. The He-280 program was canceled in favor of the new Messerschmitt Me-262 that also used a Junkers engine.

The war ended before another engine designed by von Ohain became operational.

In terms of monetary reward, von Ohain had received moderate pay increases, and about three months after the war ended he received a check for several hundred thousand now-worthless Reichsmarks from the Heinkel Co.

In 1947, the United States swept von Ohain up along with hundreds of other German scientists in Operation Paper Clip. He went to work as a research scientist at Wright-Patterson AFB, Ohio. Von Ohain continued to distinguish himself, becoming chief scientist of the Aero Propulsion Laboratory in 1975. He continued publishing and patenting until retiring in 1979.

In his retirement years, von Ohain remained active as a consultant and was selected as the Charles Lindbergh Professor at the National Air and Space Museum in 1985. Like Whittle, von Ohain received many honors recognizing his work. He died on March 13, 1998.

Whittle and von Ohain met many times in the United States, often when they were jointly receiving some prestigious honor, such as the 1991 Charles Stark Draper Prize. When they were together, von Ohain deferred graciously to Sir Frank.

Of all their meetings, the most significant took place at Wright-Patterson in May 1978. Col. Philippe O. Bouchard, commander of the Aero Propulsion Laboratory, hosted a two-day session where Whittle and von Ohain spoke freely of their experiences and answered a barrage of questions from the captivated audience.

The two men clearly enjoyed themselves, for this was recognition by people who understood the immensity of their challenge and the talent that it took to meet it.

Perhaps more important, it was perfectly obvious to Whittle and von Ohain that, at last, each man truly recognized and applauded the achievements of the other.

Jet propulsion is an application of Isaac Newton’s 1697 Third Law of Motion: For every action there is an equal and opposite reaction. Thrust out the back moves the aircraft forward.

A turbine was patented by John Barber in England in 1791.

In 1884, Charles A. Parson designed a turbine intended to convert the power of steam directly into electricity.

In 1903, Norwegian Aegidius Elling built the first turbine that sustained itself in running.

Romanian inventor Henri Coanda attempted to fly a primitive jet aircraft in 1910, using a four-cylinder internal combustion engine to drive a compressor at 4,000 revolutions per minute. It was equipped with what today might be called an afterburner, producing an estimated 500 pounds of thrust. Countless loyal Coanda fans insist that the airplane flew. Others say it merely crashed.

In 1918, General Electric established a gas turbine division. There, Sanford A. Moss moved closer to the true jet engine with his GE turbosupercharger that used hot exhaust gases to turn a turbine that drove a centrifugal compressor used for supercharging. The device was critical to the success of the B-17, B-24, P-38, and many other airplanes.

In later life, Moss would laughingly remark that he did not know how close he came to inventing the jet engine.

By 1920, Alan A. Griffith developed a theory of turbine design, based on gas flow past airfoils rather than through passages. Later he was a proponent of the turboprop engine—and an opponent of Whittle.

There were other experimenters contemporary with Frank Whittle and Hans von Ohain. American Nathan Price developed a 3,500-pound-thrust engine, and Clarence “Kelly” Johnson designed an advanced fighter to use it, but the Army Air Corps considered it so advanced that it was unlikely to be completed before World War II was over. The Army Air Corps therefore rejected it.

Walter J. Boyne, former director of the National Air and Space Museum in Washington, is a retired Air Force colonel and author. He has written more than 400 articles about aviation topics and 40 books, the most recent of which is Roaring Thunder. His most recent article for Air Force Magazine, “Gabreski,” appeared in the November 2005 issue.


Biography Hans Von Ohain

Dr. Hans von Ohain is regarded as both the father of jet propulsion and joint inventor of the jet engine. His work in the 1930’s to develop a practical turbojet engine for aircraft was mirrored (completely independently) by the British RAF engineer, Frank Whittle. Despite being on opposing sides during WWII, both men met several times later in their lives and became firm friends.

Hans Joachim Pabst von Ohain was born in Dessau, Germany on December 14th, 1911. The son of a wealthy army officer, he enjoyed a happy childhood in which he was free to indulge his passion for models and all things ‘technical’. In 1930 he entered the University of Gottingen in order to study thermodynamics and aerodynamics.

The origin of Von Ohain’s idea for a turbojet engine reputedly came about when he noticed how the vibration generated by a radial piston engine affected the stability of an airplane. He began to conceive a design for a smoother means of propulsion. After receiving his doctorate in 1935 he stayed at the university, serving as an assistant to the physicist, Robert Wichard Pohl.

He also decided (with much help from a car mechanic, Max Hahn) to build a model of his fledgling engine design, which he tested at the university. In the same year, 1936, he filed a patent application for his “process and apparatus for producing airstreams for propelling airplanes” (Patent document CH-184920). Frank Whittle had been granted a British patent for his turbojet design six years before, but there were significant differences in the two mens’ designs so von Ohain’s patent was duly granted in 1937.

The tests on his model engine didn’t go particularly well but they at least proved that the principal components – compressor, combustor and turbine – actually worked and the basic theory behind the design of the model was sound.

Lacking the funds to take his work any further, von Ohain was introduced (by his principal, Pohl) to the aircraft manufacturer, Ernst Heinkel. The Heinkel Company was impressed with von Ohain AND his ideas and quickly agreed to take him on-board and provide him with key facilities and personnel. His assistant, Max Hahn, followed along.

In the Summer of 1936, work began on the first test engine, HeS 1. It was ready to bench-test in early 1937 using hydrogen gas to fuel it. The tests went well despite problems with overheating, and work got underway to put together a true prototype capable of powering an airplane and able to run on liquid-hydrocarbon fuel. Work also got underway to build an airframe to accommodate the engine.

The new engine was called HeS 3 and was first bench-tested in the Spring of 1938. Test results were disappointing, with compression insufficient and combustion poor. A quick re-design was therefore carried out that resulted in HeS 3b, a slightly larger but simpler engine. It was flight-tested underneath an existing Heinkel airplane (an He 118) and by the Summer of 1939 a second “b” was incorporated into Heinkel’s now-completed airframe.

On August 27th, 1939, the Heinkel He 178, powered by Hans von Ohain’s engine, became the world’s first turbojet-powered airplane to fly. The jet age had begun.

For the next few years, Hans von Ohain worked on an engine that was intended to power the world’s first turbojet-powered combat aircraft, the Heinkel He 280. Progress was slow and problematic but the He 280, powered by von Ohain’s HeS 8 engine, eventually flew in April 1941 in front of German Air Ministry officials who, wholly impressed, promised further funding.

However, a number of turbojet engine and airframe projects were underway in Germany by this time and Hans von Ohain’s HeS 8 engine was ultimately eclipsed by the more practical Junkers Jumo 004. Heinkel’s He 280 fighter was also eclipsed, by the Messerschmitt Me 262, which became the first turbojet-powered fighter to go into production and be used in combat. For the rest of the war, von Ohain worked on developing a privately-funded Heinkel engine, the complex, advanced and extremely powerful HeS 011.

After WWII, as part of an American operation (Paperclip) to move top German scientists and engineers across the Atlantic, Dr. Hans von Ohain soon found himself in the USA. He became a research scientist at Wright-Patterson Air Force Base in Ohio. By 1956 he was a team leader at the Aeronautical Research Laboratory where his work was key to propulsion-research.

He became Chief Scientist of the Aerospace Research Laboratory in 1963, and in 1975 became Chief Scientist of the Aero Propulsion Laboratory where he oversaw virtually all US Air Force engine research and development. After retiring in 1979 he became an associate professor at the University of Dayton as well as the Charles Lindbergh Professor at the National Air and Space Museum. He died, aged 86, on Friday, March 13th, 1998 at his home in Melbourne, Florida.

Dr. Hans von Ohain registered numerous patents throughout his working life and was honored many times, including being inducted into the International Aerospace Hall of Fame and the Engineering and Sciences Hall of Fame. There is no doubt that Hans von Ohain was a key player in the development of aircraft propulsion for over fifty years, both in Germany and later in the US, but he will be chiefly remembered as the man who built the engine that took mankind into the jet age.


Hans von Ohain

Hans Joachim Pabst von Ohain (14 December 1911 – 13 March 1998) was a German physicist, and the designer of the first operational jet engine. [1] His first test unit ran on externally supplied hydrogen in March 1937, and it was a later development that powered the world's first flyable all-jet aircraft, the prototype of the Heinkel He� (He 178 V1) in late August 1939. In spite of these early successes, other German designs quickly eclipsed Ohain's, and none of his engine designs entered widespread production or operational use.

Ohain started to develop his first turbojet engine designs independently during the same period that Frank Whittle was working on his own similar designs in Britain, and their turbojet designs are said by some to be an example of simultaneous invention. [2] However, Frank Whittle was already working on his design in the late 1920s and openly patented the design in 1930, a full seven years before Ohain's design ran. The core of Ohain's first jet engine, the Heinkel HeS𔀳, which he described as his 'hydrogen test engine' was run 'in March or early April' according to Ohain (although Ernst Heinkel's diaries record it as September 1937) [3] but it was not self-sustaining, requiring externally supplied hydrogen. [4] The engine required modifications to cure overtemperature problems and to fit a fuel system to enable it to run self-contained on liquid fuel which was achieved in September 1937, [5] [6] . Ohain's jet engine was the first to fly operationally within the Heinkel He� aircraft in 1939, which was followed by Whittle's engine within the Gloster E.28/39 in 1941. [7] Operational jet fighter aircraft from both Germany and Britain entered operational use virtually simultaneously in July, 1944. [8] After the war the two men met and became friends. [9]


The Birth of the Jet: The Engine that Shrunk the World

In today’s time it is easy to take for granted the complex inventions that alleviate our everyday life. The modern jet propelled airplanes for example, are one of the biggest drivers behind rapid globalisation and play a major role in world trade. Nevertheless, the development that revolutionised aviation and inaugurated the era of jumbo jets came in a time of European and World conflict. It was at the dawn of World War II that two engineers from opposing sides of the war, separately and unaware of the other’s contribution, engineered the Jet Engine that would shrink the world in the 20 th century and set the groundwork for other milestones in aviation such as supersonic flight and space exploration.

The notion of jet propulsion has been around for centuries. The concept of jet engines can actually be traced back to the first century AD, when Hero of Alexandria introduced the “aeolipile”. This machine used pressurised steam forced through two jet nozzles placed on the surface of a sphere so as to force the sphere to spin rapidly on its axis [1]. Jet propulsion got off to its “flying start” with the Chinese invention of the rocket used for fireworks in the 11th century. By the early 20th century jet propulsion was a known principle and viewed as a potential alternative to standard propeller engines, especially in high-speed flight. By the 1920s jet engines, powered by an external power source, were used to propel racing planes but proved to be inefficient for low-speed flight.

On the German side of WWII a young German physicist, Hans von Ohain, was at the forefront of research into jet propulsion [2]. Hans von Ohain was born in

Heinkel He 178, the world’s first aircraft to fly purely on turbojet power, using an HeS 3 engine (Photo credit: Wikipedia)

Dessau on December 14, 1911 and received his Ph.D. in Physics and Aerodynamics from the University of Göttingen. During his studies he established the notion that one could build “an engine that did not require a propeller.“ Von Ohain’s first attempt to build a jet engine, which he patented in 1936, was not a great success. The jet engine had been built by an automotive engineer, Max Hahn, but ran into serious problems with combustion stability [3]. Most of the fuel would not ignite within the engine but would combust in the outside air. This caused flames to shoot out the back and prompt the electric motor powering the compressor to overheat. When Ernst Heinkel, one of the largest German aircraft manufacturers of the time, heard of von Ohain’s work he recognised the promise of the design and started to provide financial and technical funding [1]. After a two-month period of research on the airflow in the engine Max Hahn, von Ohain and Heinkel’s best engineers completed construction of a totally new engine that ran on hydrogen. As the high-temperature hydrogen exhaust damaged the metal framework, the old HeS 1 engine was refined to run on gasoline, a centrifugal compressor and axial turbine stages. This new engine, the HeS 3b, was then fitted to a new test airframe, the Heinkel He178. On August 27, 1939 the Heinkel He178 took off from Marienehe aerodrom and was thus the first jet-powered airplane. In 1940 the engine designer Anselm Franz developed the Jumo 004 engine with an axial-flow turbojet, as opposed to the centrifugal-flow designs [4] of the original von Ohain engines. This engine was used to propel the Messerschmitt Me262 in 1942, the only jet fighter airplane in WWII.

At about the same time in England Frank Whittle, born on June 1, 1907 in Earlsdon as the son of a mechanic, developed his version of the jet engine unaware of von Ohain’s achievements. In a 1928 in an astonishing student essay Future Developments in Aircraft DesignWhittle showed that at increasing altitudes of flight the lower outside pressure and density of air would reduce drag with subsequent improvements in fuel efficiency and flight speed. In these conditions Whittle

The Whittle W.2/700 engine flew in the Gloster E.28/39, the first British aircraft to fly with a turbojet engine, and the Gloster Meteor (Photo credit: Wikipedia)

contemplated speeds of 600 mph at 60,000 feet when at the time the fastest RAF plane flew at 150 mph at a maximum altitude of 15,000 feet. However, current designs based on the internal combustion engine were being starved of oxygen at higher altitudes, which essentially limited current fighter planes to lower and slower flight conditions. Whittle therefore proposed a new form of propulsion – the jet engine.

Whittle’s patent showing a centrifugal-flow engine with a multi-stage axial followed by a centrifugal compressor was granted in 1932. Unluckily Whittle was unable to excite either RAF nor the government to fund his work. Therefore he, Rolf-Dudley Williams and J. Tinling, two ex-RAF men who were interested in his work, incorporated the Power Jets Ltd. Even though the company only received minimal funding from outside investors, Power Jets were able to complete and run their first engine, the Whittle Unit, on April 12, 1937. This achievement triggered the interest of the Air Ministry, which now started to grant minimal amounts money in order to develop a flyable version. On May 15, 1941 the revised engine W.1 with 3.8 kN thrust and manufactured by Rover was fitted to the Gloster E.28/39 airframe and took off for a flight of about 17 minutes with a maximum speed of 545 km/h. Rolls-Royce then took over the development and production of the Whittle engine, which led to the Whittle-type Rolls-Royce Welland and the W.2 engines [5]. These new designs were used to propel the interceptor Gloster Meteor 1 in 1944.

After the war the British shared Whittle’s technology with the United States, enabling the engine-builder General Electric (GE) to build jet engines for America’s first jet fighter, the Bell XP-59. Another American jet engine designer Pratt & Whitney improved the fuel economy of jet engines, while a General Electric engineer named Gerhard Neumann introduced the variable stator preventing jet engines from gulping in too much air and restraining them from losing all their thrust [5].

During the last 40 years jet engines have been improved in a variety of ways, and have also been combined or replaced with rocket engines. For example, manned superplanes like the rocket-powered X-15 can fly almost 7 times the speed of sound, while the new A380 can transport up to 800 passengers in a luxurious ambience. It is remarkable to say that the early steps taken by Whittle and von Ohain laid the foundation for all these new magnificent aircraft.

Diagram of a typical gas turbine jet engine (in English). Air is compressed by the fan blades as it enters the engine, and it is mixed and burned with fuel in the combustion section. The hot exhaust gases provide forward thrust and turn the turbines which drive the compressor fan blades. (Photo credit: Wikipedia)


Post-World War II

In 1947, Ohain was brought to the United States by Operation Paperclip and went to work for the United States Air Force at Wright-Patterson Air Force Base. ⎖] In 1956 he was made the Director of the Air Force Aeronautical Research Laboratory and by 1975 he was the Chief Scientist of the Aero Propulsion Laboratory there. ⎖]

During his work at Wright-Patterson, Ohain continued his own personal work on various topics. In the early 1960s he did a fair amount of work on the design of gas core reactor rockets which would retain the nuclear fuel while allowing the working mass to be used as exhaust. The engineering needed for this role was also used for a variety of other "down to earth" purposes, including centrifuges and pumps. Ohain would later use the basic mass-flow techniques of these designs to create a fascinating jet engine with no moving parts, ⎜] in which the airflow through the engine created a stable vortex that acted as the compressor and turbine.

This interest in mass-flow led Ohain to research magnetohydrodynamics (MHD) for power generation, ⎝] noting that the hot gases from a coal-fired plant could be used to extract power from their speed when exiting the combustion chamber, remaining hot enough to then power a conventional steam turbine. Thus an MHD generator could extract further power from the coal, and lead to greater efficiencies. Unfortunately this design has proven difficult to build due to a lack of proper materials, namely high-temperature non-magnetic materials that are also able to withstand the chemically active exhaust. Ohain also investigated other power related concepts. ⎞]

He also invented ⎟] the idea of the "jet wing", in which air from the compressor of a jet engine is bled off to large "augmented" vents in the wings to provide lift for VTOL aircraft. A small amount of high-pressure air is blown into a venturi, which in turn sucks a much larger volume of air along with it, thus leading to "thrust augmentation". The concept was used in the Rockwell XFV-12 experimental aircraft, although the market interest in VTOL aircraft was short-lived. He participated in several other patents. ⎠]

Ohain was the influence in shifting the mind of Paul Bevilaqua, one of his students at WP-AFB, from math to engineering, ⎡] which later enabled Bevilaqua to invent the Rolls-Royce LiftSystem for the JSF F35B STOVL: "in school I learned how to move the pieces, and Hans taught me how to play chess". ⎢] Ohain also showed Bevilaqua "what those TS-diagrams actually mean". ⎣]

During his career, Ohain won many engineering and management awards, including (among others) the American Institute of Aeronautics and Astronautics (AIAA) Goddard Astronautics Award, the United States Air Force Exceptional Civilian Service Award, Systems Command Award for Exceptional Civilian Service, the Eugene M. Zuckert Management Award, the Air Force Special Achievement Award, and just before he retired, the Citation of Honor. In 1984–85, Ohain served as the Charles A. Lindbergh Chair in Aerospace History, a competitive senior fellowship at the National Air and Space Museum. ⎤] In 1991 Ohain and Whittle were jointly awarded the Charles Stark Draper Prize for their work on turbojet engines. Ohain was elected a member of the U.S. National Academy of Engineering (NAE). ⎖]


Hans Ohain - History

SP-4306 Engines and Innovation: Lewis Laboratory and American Propulsion Technology

Jet Propulsion: Too Little, Too Late

[ 41 ] Late in 1943, when the first turbojet engine was brought to the Cleveland laboratory, the entire subject of aircraft jet propulsion was so secret that only eight members of the laboratory staff were aware that the British and the Germans had actually flown aircraft powered by this radically new type of engine. Ben Pinkel, Chief of the Thermodynamics Division, recalled that he and seven other members of his division were summoned to the Administration Building to a special meeting with Ray Sharp and Colonel Donald Keirn of Wright Field. They were sworn to secrecy and told the remarkable story of how the United States had obtained a valuable piece of technology from the British-the plans for the Whittle turbojet engine. 1

Keirn reported that in April 1941 General Arnold had learned during a visit to England of the development of a turbojet engine by Air Commodore Frank, Whittle. At a meeting at Lord Beaverbrook's estate outside London, Arnold was surprised when his host, Churchill's minister of aircraft production and one of his most intimate advisors, turned to him and said, "What would you do if Churchill were hung and the rest of us in hiding in Scotland or being run over by the Germans, what would the people in American do? We are against the mightiest army the world has ever seen". Those present at the meeting agreed that Germany could invade England "anytime she was willing to make the sacrifice". 2 This was the context in which Great Britain agreed to turn over the plans for the Whittle turbojet engine, provided utmost secrecy were maintained and a strictly limited number of persons were involved in its development. Arnold personally inspected the Whittle engine several weeks before its first flight and arranged to have General Electric's Supercharger Division at West Lynn, Mass., take on the American development of Whittle's prototype. Arnold selected Bell Aircraft of Buffalo, N.Y., to work concurrently on an airframe for a fighter, or pursuit-type aircraft. 3

Arnold dispatched Keirn to England in August. He returned two months later with the plans for the Whittle W2B (an improvement of the original model), and an actual engine, the W1X. In addition to the plans and the engine itself, Keirn arranged to bring, to the United States one of Whittle's engineers and several technicians. Frank Whittle himself, the new engine's designer, visited the project during the time of intense development at General Electric's Supercharger Division at West Lynn, Mass. So new was the concept of a compressor-turbine combination propelling an airplane that, even with the plans and the reassembled engine, the supercharger experts remained skeptical. The British engineer recalled that "until we pushed the button and showed this thing running, the Americans wouldn't believe it would work". 4 The General Electric group [ 42 ] succeeded in translating the British specifications and produced, not without difficulty, an American copy of the Whittle engine.

Arnold's selection of the General Electric Supercharger Division was no coincidence. In 1917, at a time when there was a general lack of interest in superchargers, Sanford Moss pioneered the development of a turbo supercharger, a turbine that utilized the waste gases in the engine exhaust, a concept first advanced by the Frenchman Auguste Rateau. At General Electric's West Lynn Plant this work continued under Army sponsorship until Moss retired in 1937. Part of the success of the General Electric turbo supercharger must be attributed to the development of materials for the turbine. Special alloys, such as Hastelloy B for the turbine blades, Timkin alloy, and later Vitallium for the turbine disks, enabled the turbine to withstand the extreme temperatures of the gases that passed through it. 5

Colonel Edwin R. Page, Chief of the Power Plant Branch at Wright Field from 1926 to 1932, played an important role in encouraging Moss's work. Page calmly kept faith, despite what appeared to be an enormous waste of government funds, while turbines at General Electric exploded to the right and left of him. 6 Because of his association with the development of General Electric's supercharger, the Army called on Colonel Page to nurture the relationship between General Electric and the fledgling NACA laboratory in Cleveland. He was appointed the laboratory's first Army liaison officer in May 1943.

So secret was the development of the Whittle engine that only after the classification of the project was downgraded from "super-secret" to "secret" early in the summer of 1943 was Keirn allowed to inform the NACA of this important project-over two years after Arnold's visit to England. Keirn furnished the select group at the meeting in Sharp's office with a set of plans by General Electric for a jet Propulsion Static Test Laboratory, which was begun in July. Pinkel picked Kervork K. Nahigyan to head the new jet Propulsion Section.

In September contractors had hastily completed an inconspicuous one-story building at the Cleveland laboratory. It was surrounded by a barbed wire fence at the edge of the airport's runway. A heavily guarded truck delivered the General Electric I-A for testing. 7 The Static Test Laboratory consisted of spin pits lined with wood to protect workers from the dangers of blades flying off in all directions when engine compressors reached their limits during endurance testing. The secret work carried on in this modest structure, set apart from the carefully designed permanent laboratory buildings for the investigation of the piston engine-would, after the war, become the major effort of the entire laboratory.

If the success of the Whittle engine was news to the group in Sharp's office, the jet propulsion concept was not. Pinkel and Nahigyan had assisted work at Langley on a jet propulsion device, inspired and directed by one of the NACAs outstanding aerodynamicists, Eastman Jacobs. The Army had unceremoniously canceled this project, the previous February.

Before World War II, many experts throughout the world shared the assumption that better aircraft engines would result from small improvements of the components of the piston or reciprocating engine. Because the aircraft engine was an adaptation of the automobile engine, radical innovations were expected to appear first in the automobile engine. Roy Fedden, then an engineer for the Bristol Aeroplane Company, wrote in an article ironically titled, "Next Decade's Aero Engines Will Be Advanced But Not Radical published in the Transactions of the Society of Automotive Engineers in 1933: "I do not anticipate any radical changes in the type of four-cycle internal-combustion engine as used today. When the present form of gasoline engine is superceded by a radically different power unit, it seems logical that this development will [ 43 ] most probably be accepted first in the automotive field before it is introduced into aircraft". 8 Fedden's prediction was wide of the mark, for it was precisely Whittle's independence from the automotive background of traditional power plant experts that enabled him to seek a new engine uniquely suited for flight.

In 1940 the sections within Langley's Power Plants Division reflected the conventional, incremental approach to the reciprocating engine. Unconventional power plants, radically new means of aircraft propulsion, had no place in the research of the division. Typical of the evolutionary rather than revolutionary, approach to engine development during the 1930s was the study of the fin geometry necessary to cool individual cylinders. NACA research suggested methods to improve the baffles and cylinder, shrouds to direct air around the cylinder for better cooling. One of the important reports issued by the NACA in 1939 concerned a method for predicting how much engine temperatures would fluctuate as the ambient air temperature changed. Cylinders from seven engine types were compared to establish this prediction method. 9

The architects of the turbojet revolution, however, did not inherit the evolutionary approach of automotive engineers. Whittle and Hans von Ohain (who developed a turbojet independently in Germany were able to look at aircraft propulsion with a freshness lacking among the engine experts in Europe and the United States. The positive qualities of flying the gas turbine made up for the deficiencies observed in stationary industrial turbines. Whittle wrote: "There seemed to be a curious tendency to take it for granted that the low efficiencies of turbines and compressors commonly cited were inevitable. I did not share the prevalent pessimism because I was convinced that big improvements in these efficiencies were possible, and, in the application of jet propulsion to aircraft, I realized that there were certain favorable factors not present in other applications". 10 The first positive factor that he singled out was that low temperatures at high altitudes actually made the engine more efficient. More energy was available to power the airplane. Second, Whittle thought the forward speed of the aircraft created a ram effect, which increased the efficiency of the compressor third, only a portion of the energy released into the turbine had to be used to drive the compressor-the rest could be used for propulsive thrust. These were the criteria of an engineer-test pilot. Although Whittle also had a strong background in aerodynamics, it did not play a significant role in his early thinking.

Jet propulsion was not a new idea when Frank Whittle and Hans von Ohain took up the gas turbine problem. 11 Every airplane, in fact, is propelled by a stream of air. The forward motion of.

Arnold appointed Colonel Edwin R. Page to be the Army's liaison with the laboratory in 1943 because of his expertise in turbo-supercharger development.

[ 44 ] . any body through the air depends on Newton's third law: for every action there is an equal and opposite reaction. In airplanes powered by a reciprocating engine, the propeller creates a jet of air that rushes backward to drive the aircraft forward. In a jet engine, however, the air is funneled into the engine, compressed, and heated. The air stream has reached a high velocity by the time it is ducted out the back end. Jet propulsion devices were conceived as early as c. 150 B.C. when Hero of Alexandria designed an aeolipile that produced jets of hot steam to rotate a spherical ball. In the late 18th century a British inventor patented the first gas turbine design, and by the early 20th century, through the innovations of Charles Parsons and others, industrial steam turbines were in general use for power generation. However, until the early 1930s few dreamed that the heavy turbines then in industrial use could be made light enough to be flown. Between the concept of a gas turbine and a successful aircraft engine flies the pitted terrain of development.

Successful development involves a combination of technical ingenuity and determination on the part of the inventor. A less tangible factor, the role of scientific theory in invention, is more difficult to determine. 12 In the case of the turbojet, the theoretical understanding of the science of fluid mechanics was far ahead of the ability to design practical machines. Although American and German theorists had directed attention to an understanding of the aerodynamics of both axial and centrifugal superchargers for aircraft, there is little evidence that this understanding played a direct role in the development of the turbojet.

When Whittle began to consider the idea of using a gas turbine to propel an airplane about 1928 to 1929, many engineering experts had already concluded that jet propulsion had no future. The report prepared at the National Bureau of Standards by Edgar Buckingham at the request of the engineering division of the U.S. Air Service in 1923 was typical of generally accepted opinion. Buckingham's report concluded that at the highest speeds (which at the time were not more than 250 miles per hour) a jet engine would consume five times the amount of fuel of a conventional engine-propeller combination. He thought that its weight and complexity would make flying impossible. Buckingham recommended against any further research on jet propulsion, conceding only that if thrust augmenters could be made workable, there might be some future for a jet propulsion device as a prime mover. 13

This suggestion may have encouraged Eastman Jacobs to take up the problem of thrust augmenters in 1926. Although this work had no practical application at the time, "this study stiffed in Jacobs the beginnings of a strong interest in high-speed aerodynamics". 14 As early as 1935, at the Fifth Volta Congress in Rome, Italy, the world's leading aerodynamicists, gave serious consideration for the first time to the theoretical feasibility of flight at speeds at or faster than the speed of sound. A German aerodynamicist, Adolf Busemann, suggested in his Volta paper that a sweptback wing could solve some of the compressibility problems that aircraft would encounter at extremely high speeds. 15 However, in the 1930s aerodynamicists and propulsion experts did not see how their fields complemented each other. Although theoretically it seemed possible to fly faster than the speed of sound, a propeller-driven aircraft could never reach the necessary speeds. The engine manufacturers were oblivious to the implications of the high-speed conference. According to von Ohain, "it should have scared the hell out of them. because that showed that the airplane, sooner or later, could easily break the supersonic barrier". 16 That would render the piston engine obsolete.

However, contrary to Edward W. Constant's thesis in The Origins of the Turbojet Revolution , Whittle and von Ohain revolutionized aircraft propulsion, not because of a knowledge of aerodynamics superior to that of American engineers, but through their insight that the [ 45 ] combination of compressor and turbine was uniquely suited as a power plant for flight . 17 Although the potential problem of compressibility as propeller tip speeds neared the speed of sound should have influenced Whittle and von Ohain, there is little evidence that this relatively unstudied phenomenon in the 1930s was a factor in their decision to look for a radically new type of power plant for aircraft. Rather, it appears that both were drawn to the turbojet because of its simplicity and potential as a power plant specially adapted to aircraft. It was their independence from the automotive-aircraft engineering tradition that enabled them to think outside the paths of accepted practice. When they began their work, the aircraft reciprocating engine had become a mind-boggling example of mechanical complexity. To attain higher speeds, designers added cylinders to increase power. To compensate for the decreased density of the air at higher altitudes that reduced power, they added superchargers. With added cylinders and superchargers, cooling became a problem solved by the addition of yet another component, the intercooler. In contrast to the difficult to maintain array of components and subcomponents, the turbojet offered the possibility of a light-weight engine of extraordinary simplicity. The engine, as conceived by Whittle and von Ohain, potentially could perform better at the higher altitudes that caused problems for the reciprocating engine, and its efficiency was likely to increase with speed.

Like Whittle, von Ohain started with the idea that flight required a power plant specially adapted to motion through the air. His enthusiasm stemmed from the insight that an engine that burned continuously was "inherently more powerful, smoother, lighter and more compatible with the aero-vehicle" than the clumsy four-stroke cycle of a piston engine. His first idea was to "accomplish this process without employing moving machinery by bringing the inflowing fresh air in direct contact with the expanding combustion gas," a kind of ram jet. 18 However, he soon realized that in order to get an efficient engine he needed to separate the two phases of compression and expansion. He finally arrived at a turbojet configuration similar to that of Whittle, whose 1930 patent he did not discover until after the development of his own design. 19 Von Ohain's engine powered the first flight of a turbojet plane in August 1939 from the Marienehe Airfield in Germany.

Although the turbojet created a revolution in aircraft propulsion,, it was not as radical a break with the technology of the reciprocating engine as the word revolution might imply. The technology of the supercharger, a component added to the reciprocating engine, provided the continuity between the old technology and the new. The supercharger was, in fact, a compressor. However, in the turbojet, the compressor took its place as an intrinsic part of the engine system. For the inventors, the choice of the compressor was significant, and it was not by chance that both Whittle and von Ohain chose a centrifugal compressor the centrifugal supercharger was in common use in conventional engines. In contrast, axial superchargers were extremely demanding experimental devices. Both von Ohain and Whittle knew that the centrifugal compressor was a "brute force device" and that eventually they would "go, axial," but they started with the centrifugal compressor because it was simpler to build. 20 In the same year that von Ohain demonstrated the feasibility of the turbojet concept, Anselm Franz, Germany's expert on super-chargers, designed the first turbojet with an axial-flow compressor.

Independent American Efforts to Develop a Turbojet

Sir Henry Tizard, science advisor to the British Ministry of Aircraft Production, visited the United States in September 1940. Although it is well known that Tizard informed his American allies of British technical advances in radar and opened discussions concerning British [ 46 ] cooperation in the development of atomic energy, Tizard also brought with him the first news of the British developments in the new field of jet propulsion. Tizard met with both Vannevar Bush and George Lewis, but he revealed very little except the seriousness of British efforts in jet propulsion. Bush later recalled: "The interesting parts of the subject, namely the explicit way in which the investigation was being carried out, were apparently not known to Tizard, and at least he did not give me any indication that he knew such details". 21

In February General Arnold became aware of new and unforeseen developments in aircraft propulsion from German intelligence sources. At first Arnold appears to have identified jet propulsion with rocket-assisted take-off, and he encouraged the setting up within the NACA of a subcommittee on auxiliary jet propulsion. However, on February 25, 1941, after hearing reports of European developments of jet-assisted take-off and, more ominous, as a primary source of power, engine research took on new urgency. He asked Vannevar Bush, then Chairman of both the National Defense Research Committee (NDRC) and the NACA, to form a jet propulsion committee with a much wider mandate. He was concerned that the Germans' experimental use of rockets to assist take-off would make existing fighter planes obsolete. Arnold considered the Army supported work at the California Institute of Technology inadequate. He did not expect this group, led by the irrepressible Frank Malina. and advised by aerodynamicist Theodore von Karman, to yield "practical results" in the near future. Arnold stressed the urgency of giving the problem to a "large group of able scientists". 22

In his response to General Arnold, Bush firmly disabused him of any wishful thinking that jet propulsion research should be undertaken by the NDRC rather than the NACA. He pointed out that, while rockets as weaponry could legitimately come under the purview of the NDRC, aircraft propulsion was the province of the NACA, an organization he greatly admired and may have used as his model when the country called upon him to mobilize science. 23 He acknowledged that the well-known physicist from the California Institute of Technology, Richard C. Tolman, was investigating "certain aspects of rocket propulsion," but he anticipated that the research in jet propulsion would be long and expensive. He did not think that it was "proper for NDRC to devote its funds to aircraft propulsion problems". Bush therefore recommended the formation of a special committee that would act independently but under the general umbrella of the NACA Power Plants Committee. 24

Before deciding on the composition of the committee and a suitable chair, Bush consulted with Rear Admiral John H. Towers, Chief of the Bureau of Aeronautics. Towers agreed with Bush that the committee should be composed of "personnel other than those who deal with conventional power plants" and focused on high-level scientists. He looked on Hugh L. Dryden of the Bureau of Standards as "particularly suitable for such a committee, where practicability should be combined with theoretical considerations". 25

After canvassing several prominent members of the aeronautical community, Bush selected Stanford University's emeritus professor, William Frederick Durand, still vigorous at the age of 82, to head the new committee. Durand was a man of intellect and professional integrity "calm tolerance and the driving power of a will to work". 26 Durand had served as Chairman of the NACA from 1917 to 1918. He had made his reputation in the field of aeronautics through a systematic presentation of propeller performance data (with Everett Parker Lesley), a standard reference work relied on by early aircraft designers. Durand's reputation as a scientist was enhanced through his role as editor of a definitive multi-volume work on aerodynamics in the 1930s. In urging Durand to assume leadership of the committee, Bush wrote: "The matter is of [ 47 ] such importance, however, and so definitely requires mature and independent judgment of a high order, that I believe it is worthy of your attention as chairman, no matter how much you might be relieved on the details of the work." The scope and the authority of this new committee was to be extremely wide. Bush wrote that after consultation with Arnold, they agreed that if the committee concluded that "full-scale experimentation was in order," they would find "several million dollars" to fund it. 27

The new Special Committee had a broad responsibility to investigate all aspects of jet propulsion. Even members of the NACA would be asked to serve only in an ex officio capacity: "The backbone of the committee should be men of independent background and with them should be joined men of special capabilities in the process of evaluation". 28 Pratt & Whitney, Wright Aeronautical, and Allison, the major manufacturers of piston engines, were deliberately excluded from participation on the committee, despite the interest that each company had shown in early jet propulsion schemes. For example, Pratt & Whitney had supported the development of a design by Andrew Kahtinsky of the Massachusetts Institute of Technology and by December 1941 had learned of the successful flight of Whittle's engine from a friend of the pilot "who flew the British straight propulsion machine". 29 Wright Aeronautical may have learned of the Whittle engine during Tizard's visit and attempted in 1941 to negotiate for the American license from Whittle's Company, Power jets, Ltd.

Representation by industry was limited to three manufacturers, all with prior experience not with aircraft engines, but in industrial steam turbine design: Allis-Chalmers, Westinghouse, and the General Electric Steam Turbine Division at Schenectady, NY The rationale for excluding the engine companies from membership on the committee was not that they were too over-burdened with war-related work, because the steam turbine manufacturers were in the same situation. What Bush seems to have meant by the euphemism, "special capabilities in the process of evaluation," was that the engine companies, with a vested interest in maintaining the status quo, should not be included. Bush knew that engineers who worked with steam turbines had experience with the aerodynamics of compressors and turbines. In addition to these manufacturers and representatives of the military, Bush recommended three scientists: Professor C. Richard Soderberg of the Massachusetts Institute of Technology, an authority on turbines who shouldered the duties of vice-chairman A.G. Christie of The Johns Hopkins University, and Hugh Dryden. The deliberate omission of the aircraft engine manufacturers may have led the committee to underestimate what a demanding undertaking it would be to develop a new aircraft engine. More.

William F Durand, chairman of the NACA's Special Committee on jet Propulsion.

[ 48 ] . important, the selection of steam turbine manufacturers influenced the choice of the axial-flow compressor with multiple stages, a compressor used in industrial steam turbines. If the engine companies had been included, they would have been more likely to favor a design with a centrifugal compressor because of their experience with superchargers. In hindsight, it would have been wise to include at least one design based on the centrifugal compressor.

By April 1941 the Special Committee, was ready to get to work, but the minutes show how far they were from the turbojet concept. Still sharing Arnold's impression that jet propulsion involved rockets, the committee considered and dismissed Goddard's rocket experiments. By consensus, the committee decided that the problem of jet-assisted take-off was of greatest importance and "the most immediately practical". Obviously, Arnold had made information on the striking results of the California Institute of Technology's JATO (jet-assisted take-off) rockets available to the group. 30

Eastman Jacobs was invited to give a full report on the progress of the jet propulsion project that the NACA had begun at its laboratory at Langley. No doubt Jacobs's invitation to make this presentation to the committee was due in part to the enthusiasm that Vannevar Bush had already developed for the NACA scheme. In the letter he wrote to Durand asking him to chair the committee, he revealed that, of the many jet propulsion proposals already submitted to the Army, the Navy, and the NACA, the Jacobs project seemed to hold the most promise. "The group at Langley Field and Jacobs, in particular, have been very active in developing one jet propulsion scheme in which I have acquired a large amount of interest and perhaps even enthusiasm, for it seems to have great possibilities and I cannot find any flaw in their arguments." 31

Jacobs's scheme for a ducted fan, nicknamed "Jake's jeep" by his NACA colleagues, was among several embryonic efforts to develop a gas turbine power plant for aircraft in the United States prior to the importation of the Whittle engine. 32 Jacobs received the high-level support of Bush and Durand. As a result of his prestige, the designs that the industry representatives on the Durand Committee later developed owed a great deal to preliminary studies made at Langley. Jacobs was riding a crest of prestige for the development of NACA laminar-flow airfoils. His reputation as an aerodynamicist made the NACA effort more credible than other proposals.

About 1931 the Italian Secondo Campini had first conceived a ducted-fan engine design, and Jacobs may have learned of this scheme when he attended the Volta Congress in Rome in 1935. The ducted fan, a hybrid scheme consisting of a conventional piston engine and compressor, lacked the simplicity of the turbojet. Air entered a long cylindrical nacelle through a duct, where it was compressed. The section of the nacelle in back of the compressor served as a combustion chamber. Fuel was injected into the chamber and ignited. The heated gases, directed out the back through a high-speed nozzle, produced thrust to drive the engine forward. The Campini engine had a two-stage centrifugal compressor Jacobs modified Campini's design. He chose an axial compressor with two stages. Jacobs had problems not only with the compressor, but also with the combustor, which failed to function properly. 33 Nevertheless, in the view of Clinton E. Brown, who worked on the project, the jeep was a sound idea. Jacobs proved the feasibility of his ducted fan concept. 34 However, compared to Whittle's far simpler design for a turbojet, its development in 1941 was embryonic.

In April 1941, prior to Arnold's return from England, the Jacobs engine looked promising enough to win the backing of the country's gas turbine experts. In its early stages, the project had consisted of a "simple program of burning experiments". It was only after Durand placed the full weight of the Special Committee on jet Propulsion behind the project that Jacobs expanded the [ 49 ] scope of the work from a simple burner test rig to "more nearly a mock-up of a proposed airplane for ground testing". 35

At the April 22 meeting, members of the Special Committee also heard summaries of British reports on the development of axial-flow compressors, probably those of A. A. Griffith and Hayne Constant of the Royal Aircraft Establishment, who had been working for many years, with limited success, on axial compressors. Their goal was a gas turbine engine to drive the aircraft's propellers. What the Special Committee could not know was that Whittle had chosen not to use the more complicated axial configuration for his turbojet engine.

By the May 8 meeting, Arnold had returned to the United States, and the Special Committee expected to be briefed on the latest developments. Instead, because of the British imposition of a "most secret" classification on the project, the committee was merely asked to suggest the names of two engineers to be sent to England to "make contact" with British developments in jet propulsion. Durand, betraying his mistaken belief that the new British propulsion system used the axial compressor, suggested D.R. Shoults of General Electric, "an expert in matters relating to axial-turbo compressors, which type of equipment forms the core of the British development. 36 At the same meeting, Lewis, sharing the same prejudice in favor of the axial-flow compressor, referred to the eight-stage compressor developed by Eastman Jacobs and Eugene Wasielewski intended primarily as a supercharger. He revealed that General Electric "was interested in developing this compressor to its full capacity since the Committee's tests had been limited to low speeds and the use of only six of the eight stages which had been provided." At this point, all the signs indicated that an axial compressor would be a significant component of any jet propulsion scheme, a presumption shaped by the influence of Jacobs and the knowledge of the publications of the British aerodynamicists, Griffith and Constant. Future engineering practice would vindicate this decision, since the axial compressor did eventually prevail over the centrifugal. 37 For short-term wartime needs, however, Jacobs underestimated the axial-compressor's recalcitrant problems. The NACA would pay dearly in terms of lowered prestige for its early commitment to axial compressor development and its failure to recognize the definite advantage of the compressor-turbine combination embodied in Whittle's turbojet.

In early June Arnold sent a brief but significant memorandum to Bush. It contained as attachments a picture of the Whittle engine and a short description that had been sent by diplomatic pouch from Lieutenant Colonel J. T. C. Moore-Brabizon of the Ministry of Aircraft Production. Item one of the description stated: "The Whittle jet propulsion engine consists of 10 combustion chambers (equivalent to the cylinders of a normal engine), an exhaust gas turbine, a supercharger, and an exhaust jet or nozzle". 38 Notably absent from the description was a key element. Was the "supercharger" (i.e., the compressor) axial or centrifugal?

By the end of the month, Arnold appears to have recognized the possible superiority of the compressor-combustor-turbine combination to the hybrid piston engine-compressor-combustor combination of Jacobs's conception. In a letter dated 25 June 1941, Arnold wrote to Bush, concerning the Jacobs project: "As regards the 'Jacobs' engine, the Air Corps will stand ready to assist this project to the maximum extent possible however, further conferences with N.A.C.A. personnel and further investigation of the project as a whole indicate that this development is far from ready for a test installation". Speaking in the context of his personal knowledge of the British success with the Whittle engine, Arnold urged the Special Committee to consider not only jet-assisted take-off, but also jet engines as "primary sources of power". 39

The NACA eight-stage axial-flow compressor designed by Eastman Jacobs and Eugene Wasielewski.

In June Durand informed the committee of the Whittle project, but only in general terms because of the classification of the project. The inquiries of Wright Aeronautical to obtain the license to the Whittle engine from Power jets, Ltd., however, caused a brief diplomatic flurry, since it created the impression that the British-American agreement on the Whittle was common knowledge. As a memorandum from Bush to Arnold indicated, they had been extremely careful about what had been communicated:

I have checked with Dr. Durand this morning. Neither he nor I have communicated any of the explicit [sic] information regarding the Whittle engine to any individual. Dr. Durand in particular tells me that when his jet Propulsion Committee met he told them only that the British had a development along jet propulsion lines without giving them any explicit [sic] information. In fact, he did not have this information at the time himself. I am quite sure that explicit information placed, in the hands of Dr. Durand and myself has not gone elsewhere. 40

It now began to dawn on Bush that development of the Whittle engine was far ahead of the NACA project. In July he wrote to Arnold: "It becomes evident that the Whittle engine is a satisfactory development and that it is approaching production, although we yet do not know just how satisfactory it is. Certainly if it is now in such state that the British plans call for large production in five months, it is extraordinarily advanced and no time should be lost on the matter" Bush recommended that arrangements for production of the British engine in the United States should be expedited by the selection of a suitable company. He suggested either A.R. Stevenson of General Electric or R.G. Allen of Allis-Chalmers, both of whom had representatives on Durand's Special Committee. The choice would depend on which company they selected to develop the Whittle. The committee as a whole, Bush reminded him, "on account of British wishes," could not be privy to full information about the Whittle engine. Bush now qualified his support for the Jacobs project. If the Whittle engine was as advanced as it appeared, it deserved to be expedited, regardless of the promise of the Jacobs project over the long term:

[ 51 ] I am inclined to believe personally that in the long run the Jacobs development will prove to be equally or more interesting. It is certainly true, however, that the Whittle development is much further advanced. If it is really serviceable, and if it will really produce a relatively inexpensive power plant for pursuit craft which can be rapidly put into production, I feel that no time should be lost in expediting the matter. 41

By July Arnold had selected General Electric to copy the Whittle engine. D. Roy Shoults, then in England to oversee the British use of General Electric's turbo supercharger, became General Electric's representative, assisted by Alfred J. Lyon, the Army's technical liaison officer in Great Britain. In August Colonel Donald Keirn, the engineer from Wright Field who brought the news to the Cleveland laboratory two years later, took off for England to bring back the Whittle engine. Later Keirn joined the Special Committee so that he was fully informed of all the jet propulsion projects, both the "most secret" Whittle project and the "secret" projects of the Special Committee.

While Bush and Durand steadfastly supported the NACA project, from the time of his visit to England in April, Arnold had become a believer in the future of the Whittle engine. His letter to Colonel Lyon, 2 October 1941, reveals the first discussions of a possible future Army effort to preempt the jet propulsion field and thereby end the NACA hegemony over basic aeronautical research. However, with characteristic restraint, he refused to commit himself on this issue. Clearly, he saw the turbojet as a possible answer to the problem of obtaining higher speeds for pursuit aircraft, but he stopped short of predicting that the piston engine would be obsolete in ten years. The letter reveals Arnold's astute assessment of the possible dawning of a new era of jet propulsion.

I was told in England in April that in ten years there wouldn't be any more poppet valves or, as a matter of fact, any type of gas [piston] engine as we now have in pursuit airplanes, and another five years would see the end of that type of engine in all types of aircraft. I must admit that I was not as enthusiastic about such a proposition as the advocates in England were. In my 30 years in aviation I have seen too many of these things come up that are going to completely revolutionize everything and do away with all heretofore existing forms of aircraft, so while I am enthusiastic, I am not super-enthusiastic. I do not believe that we are ready at this time to start a development program tending towards the production of the jet propulsion engine on the same scale as we now have for the conventional type of gas engine. I am of the opinion, however, that it will be much easier to reach the 4,000 to 5,000 horsepower with the jet propulsion and gas turbine than it will be with the conventional type of engine. Everything points in that direction. The turbine has everything to its advantage. 42

Although not privy to the full Whittle story, the Durand committee had enough information on the Whittle engine to see the potential of the compressor-turbine combination. The committee set up a Special Compressor-Turbine Panel, chaired by R. C. Allen, manager of the Allis-Chalmers Steam-Turbine Department. It should be noted that Jacobs and his team were obviously informed of the conclusion of the panel, but persisted in their belief that the hybrid scheme would work. A letter to the panel from Henry Reid, Engineer-n-Charge at Langley, indicated that "jet propulsion can better be accomplished at present with the use of the conventional engine". 43 Reid conceded that a more radical approach to aircraft propulsion might prevail in the long run.

[ 52 ] Although they had at last hit upon the compressor-turbine combination, the panel considered only the axial-flow compressor. Whether the simpler centrifugal compressor was considered at all is difficult to determine, since all the minutes for the compressor-turbine panel have not been found. The axial compressor, because of its smaller frontal area and higher potential pressure ratio, looked more promising on paper. However, if the axial compressor was lighter and more compact, it demanded knowledge of aerodynamics. The complex movement of air across the blades of several stages presented a challenge to the designer. The fabrication of the complicated compressor was a nightmare. Vibrations created the danger that compressor blades might fly off in all directions. The simpler solution found by Whittle and von Ohain-the centrifugal compressor-eluded the steam turbine experts on the committee.

The same month that the compressor panel was formed, representatives of Allis-Chalmers visited Langley. "Their particular interest was the axial-flow compressor, which has been constructed at Langley Field," George Lewis wrote to Durand. Lewis revealed that the results of a joint investigation with General Electric would be made available, This was obviously a reference to the eight-stage axial-flow compressor of Jacobs and Wasielewski. All three of the companies selected axial-flow compressors, but they decided not to attempt as many stages. 44 Although the NACA directly influenced the axial compressors in the General Electric and Allis-Chalmers designs, influence on the Westinghouse turbojet is less clear. The Westinghouse design team may have decided to use a Brown-Boveri compressor as its model. In any case, the company was familiar with the axial configuration through experience with axial compressors in Navy surface vessels. 45

When the Durand Committee met at Langley Field in September, they recommended that Jacobs begin design studies to explore "the most suitable means for applying this system of jet propulsion to actual aircraft". They also decided that the preliminary studies of the companies could be made into actual proposals for submission to the Army or Navy. 46 The Navy approved designs for a turbojet by Westinghouse and for a type of ducted fan by Allis-Chalmers. The Army agreed to support General Electric's proposal for a turboprop.

Up to the time of the submission of the proposals, the committee had allowed considerable cooperation and exchange of information among the three companies, and the NACA was a clearinghouse for information. After the September meeting each company began to work independently, and although the upper management of each company represented on the Special Committee was aware of the parallel development of General Electric's Whittle turbojet, the design teams actually working on the respective projects were kept in the dark, Moreover, they were not allowed to exchange information with designers working on the other projects sponsored by the Special Committee until Durand wrote to General O. P. Echols for permission for greater cooperation. In recalling the "helpful attitude regarding mutual conference and interchange of data and suggestions" that the companies had enjoyed prior to the awarding of specific design contracts, he urged that it be allowed to continue. 47

While the members of the Special Committee knew about the "Whittle matter," as did selected high-level individuals at General Electric, Arnold would not allow the Whittle engine to be tested at Langley Field because of the British "most secret" classification. Nevertheless, Oliver R Echols, Chief of the Material Division, was aware of the development problems that the West Lynn team was encountering and urged Arnold to let General Electric send the Whittle engine for testing in NACA wind tunnels. In a memorandum addressed to General Arnold, 13 November 1941, he wrote: "As we get deeper into the Bell XP-59A and GE Type I Supercharger Projects, we find that [ 53 ] in order to exploit the fullest possibilities of this engine-airplane combination. it is highly desirable that we initiate wind tunnel studies as soon as possible". Echols suggested either the 16-foot tunnel at Moffet Field (Ames) or the 19-foot pressure tunnel at Langley. Noted in large letters on the memo was "Decision is NO" with the appended note: "General Echols advised that he had discussed this matter with Gen. A, this date, and that Gen. A did not wish to tunnel test at NACA in view of the "secrecy" of project. Therefore it will be necessary to proceed without tunnel tests planning on testing for 2nd attack if first attempt is a "bust". 48

If the committee had encouraged at least one American design based on the centrifugal compressor, more rapid progress would have been apparent. Kept in the dark, those making the initial decisions did not know that part of the success of the Whittle engine depended on its simple centrifugal compressor. Progress on all four of the projects of Durand's Special Committee was slow. In June 1942, Vannevar Bush raised doubts about the wisdom of exclusive reliance on the axial compressor. Referring to "the secret development being carried on by the General Electric Company on compressors for use in jet propulsion," he wanted to know whether the special panel that "had previously provided for the interchange of information on compressor design" should be reconvened. Durand responded that A. R. Stevenson, Jr., General Electric's representative on the committee 'had expressed the view that the time had passed for such an interchange of views". 49 In November Stevenson reassured the committee that, although it was behind schedule, their "troubles" were routine. These "troubles" were directly related to the compressor: "We are becoming quite worried about vibration of the blades on the axial-flow compressor". He reported that their experimental four-stage compressor, like the one at Langley, had lost its blades. "We believe it was due to fatigue caused by pulsating air force." 50 General Electric's turboprop, the TG-100/T31, reached the test stand by 1943. Although a turboprop provides more efficient propulsion at modest speeds, the gearing to connect the gas turbine to the propeller adds mechanical complexity. The simplicity of the turbojet probably induced General Electric engineers to design the succeeding model, the TG-180/J35, as a turbojet. Nevertheless, its tricky axial compressor made significant progress slow. Support for the Allis-Chalmers design for a ducted fan with double paths of cool and hot air was dropped by the Navy in 1943, when the company obtained the license to build a British Havilland-Halford jet propulsion unit.

Of the three designs submitted by the steam turbine manufacturers, only the Westinghouse 19B turbojet actually reached flight-testing before the end of World War II. The company proudly called it the "Yankee" because it was the product of American engineering. It appears that R. P. Kroon, head of the team that actually built the "Yankee," did not know of the British developments prior to 1943. However, even in the Westinghouse unit, a British idea for a ring of individual combustors around the central shaft of the [ 54 ] engine did find its way into the design. The "Yankee" engine had 24 combustor "cans". A company history relates that in July 1942, during the time that Westinghouse was struggling with its design, Stuart Way mentioned their problems in a meeting of a NACA combustion subcommittee. "It so happened that a GE man said that the problem was very simple-'all you have to do was take a tin can and punch some holes in it and you will have a combustion chamber'". 51 The story also belies the view that the two divisions within General Electric worked in complete ignorance of what the other was doing. At some point the engineers at West Lynn and Schenectady may have exchanged information, because the TG-100, the General Electric project at Schenectady, also used multiple combustor cans. Glenn Warren, one of its designers, called the idea one of the most important aspects of British-American cooperation. 52

Jacobs never had the benefit of the British solution to the combustion problem. Unaware that turbojets had already passed their bench tests in England and Germany, Langley engineers struggled to perfect Jacobs's hybrid scheme. The problem of achieving stable combustion in a continuous airstream without creating a flame that was so hot it would melt the metal sides of the apparatus was particularly recalcitrant. Jacobs tried to get the fuel to vaporize within a tubular boiler. However, he could not get his system to operate satisfactorily, and he agreed to enlist the assistance of Kemper's Power Plants Division. The "burner" problem was turned over to Ben Pinkel's Engine Analysis Section. Durand strongly supported the idea that a series of fuel jets should be tried. Pinkel assigned Kervork Nahigyan the task of redesigning the burner. Durand noted on a visit to Langley in March 1942 that both Jacobs's approach and that of the Power Plants Division appeared promising. He encouraged the rivalry between the two groups and set a deadline for an actual demonstration to the entire committee for July 15. 53 The demonstration, featuring Jacobs's solution, looked promising enough for the committee to encourage the work to be continued.

While Durand still strongly supported the Jacobs project, he realized that the NACA had a great deal at stake. As the first test flight of the General Electric 1-A engine neared, he became apprehensive. If Jake's jeep failed, it would seriously affect the prestige of his committee, perhaps that of the entire NACA. In late September, he revealed his anxiety over the NACA project to George Lewis. In a letter to Lewis from California, written several days before he was to witness the flight over Muroc Dry Lake, Durand urged Lewis to "feel quite free to take hold of and direct the work of Jacobs along the lines agreed upon earlier". There was not a great deal that they could do about the projects that were in the hands of the private companies, but, he wrote, I have.

Schematic view of General Electric's TG-180 shows the axial compressor influenced by the NACA eight-stage compressor.

[ 55 ] . however, felt a little anxious about Jacobs's work, due to the fact that the Committee is directly interested in that particular project in the sense that its success or failure will react directly on the reputation of the Committee-at least in connection with this particular work." 54 Two General Electric 1-A engines powered the Bell Airacomet (P-59A) into the sky several days later.

There can be no question that once the Whittle engine was successfully flown, it became clearer that the outlines of future development would favor the far simpler compressor and turbine combination over the unwieldy piston engine and fan combination of Jacobs's conception. Durand was enthusiastic about the "splendid results" of the tests at Muroc. He wrote to Keirn, "It really begins to look as though a definite start has been made along the lines we have been thinking about so long". 55

Durand informed members of the Special Committee that "resulting from entirely different causes" a meeting had been called "on the initiative of Army aviation" to take place in Washington, D.C., on November 13. Although no direct reference was made to the Whittle project, there could have been no question in any member's mind as to what Durand was talking about when he wrote that representatives of the Army, Navy, the Chairman of NACA, and the Chairman of the Special Committee on jet Propulsion "take a broad general view, with an attempt to evaluate its significance as a factor in our present war effort, and, if possible, to reach some decision as to the extent to which the subject merits immediate support and development". He revealed that a report on the Langley project would be presented at that time. 56 Thus, the committee was placed for the first time in a position to judge the relative merits of the two systems, Jacobs's ducted fan and Whittle's turbojet. Obviously, the Whittle turbojet was the winner because it was at a point of development well beyond that of the NACA project. Although it was not clear at the time, ultimately the complexity and the excessive amount of weight in comparison to its low thrust meant that the ducted fan could not compete with the simplicity, efficiency, and low maintenance of future turbojets. The jeep, nevertheless, played an important role in future American turbojet development because it stimulated both axial-compressor research and pioneering work on afterburners work that was continued after the move of the Power Plants Division to Cleveland.

There is little doubt that after the November meeting of the Special Committee, as far as the Army was concerned, the NACA project was dead. The failure of the jeep to win the continuing support of the Army directly affected the research program of the Cleveland laboratory. Ben Pinkel recalled that some time prior to his departure for Cleveland in December 1942, he was called to Henry Reid's office, where George Lewis reported that "officers of the military echelon" had informed him that "the war would be fought" with five reciprocating engines currently under production and "that all work on jet propulsion should be stopped in order that all effort should be directed toward those reciprocating engines". 57

Even after the Army's decision, Jacobs continued to believe in his ducted-fan design. In January 1943, after his transfer to Cleveland, Nahigyan perfected his design for a burner employing a series of liquid-injection spray nozzles, located within bell-shaped flame holders. 58 This experience made him the natural choice to head the jet Propulsion Section when Keirn brought the plans for the Static Test Laboratory from General Electric.

In late January, Jacobs himself visited the Cleveland Laboratory and, accompanied by Henry Reid, called on the Army officers at Wright Field. In a memorandum written after this visit, Reid noted the apparent lack of general overview of the jet propulsion situation. It was impossible to compare the various schemes to decide which ones were worthy of vigorous development.

A technician uses a micrometer to determine possible distortion of the turbine blades of General Electric's I-40 turbojet engine. The ring of combustor cans, immediately behind the turbine, was Whittle's solution to the combustion problem.

. because no one individual, with the exception of Durand, was fully informed of both the American and British developments. 59 Clearly, Reid and Jacobs still believed that the NACAs project was viable. However, the successful test flight of the General Electric 1-A engines in the Bell Airacomet the previous fall had sealed the fate of the Jacobs project. On 15 April 1943 the Special Committee officially resolved to drop "without prejudice" the project they had so wholeheartedly supported. 60 As Alex Roland has cogently argued in Model Research , the NACA [ 57 ] never fully recovered from the blow to its prestige from the failure of the United States to develop aircraft jet propulsion before the Europeans. 61

Viewed in the context of the abortive effort to develop the jeep at Langley, Arnold's decision to assign the Cleveland laboratory the task of solving the mechanical problems of existing piston engines takes on new meaning. He had lost confidence in the NACAs technical leadership in the propulsion field. The cancellation of the jeep took the creative, experimental work on jet propulsion away from the NACA for the duration of the war. Arnold chose to promote General Electric, a company previously only marginally involved in the development of aircraft engines, to a place on the cutting edge of jet propulsion development in the United States. Although the piston engine companies bore the brunt of Arnold's wrath for the dismal engine situation, he also punished the NACA for its belated and rather minimal efforts prior to 1941 to develop a jet propulsion scheme.

Arnold's decision to focus on developing existing piston engines to fight the war was a gamble. By 1944 the Germans were mass-producing a turbojet with an axial-flow compressor, the Jumo 004 for the Messerschmitt 262. Fortunately, Hitler did not appreciate the strategic importance of the superior speed of the turbojet, and production of the Jumo 004 came too late to make a difference in the outcome of the war. The Germans made only limited use of jet aircraft to shoot down Allied reconnaissance planes and to attack bomber missions. How close the jet engine came to making the difference in the war is revealed by a remark in a memo from Arnold in May 1944: "The jet propelled airplane has one idea and mission in life and that is to get at the bombers, and he is going by our fighters so fast that they will barely see him, much less throw out a sky hook and slow him up". 62

When Colonel Donald Keirn unveiled the plans for a jet Propulsion Static Test Laboratory for the Cleveland laboratory, the Army again assigned a role in the development of jet propulsion to the NACA. This visit, however, clearly underscored the Army's intention to limit this involvement to the testing of engines already developed by private companies such as General Electric and Westinghouse. Jacobs's jeep briefly gave the NACA license to develop a jet prototype. The Cleveland laboratory would continue to feel the repercussions of its cancellation.

By August 1943 it was clear to the leaders of the Cleveland laboratory that jet propulsion would play an increasingly important role in the future. After a survey of existing facilities, George Lewis pointed out that "when the Committee's Cleveland laboratory was laid out, no thought was given to the provision of facilities for testing jet propulsion units". 63 This omission revealed an astounding lack of vision.

Jacobs himself spent several months at the laboratory in 1944 and made such an impression on several clean-shaven young engineers that they grew beards in his honor. The precise nature of Jacobs's work in Cleveland is not clear. It appears that he continued work on his jet propulsion scheme despite the Army's cancellation. It was now "bootleg" work, carried on without official sanction. "Nothing was so secret," one of the technicians at the laboratory recalled, "as Jacobs's jet rotor." His friend Henry Melzer cut the blades for a turbojet in the machine shop. He was told that Jacobs designed the engine from information gathered by two agents in a German Bavarian Motor Works plant. Melzer recalled that Jacobs often came to the shop to watch his painstaking labor, cutting the blades to conform to the so-called German configurations. One afternoon Jacobs called Meltzer to let him know that they were going to start the unit in a test cell. "While it was running, we stepped over it and felt for vibrations. About a year later, we heard that another engine had exploded, and the blades had gone off in all directions. We were lucky taking that chance". 64

Secret jet propulsion tests of General Electric's I-16 were carried out in the Static Test Jet Propulsion Laboratory, completed in September 1943.

By March 1944 Lewis reported on the "change in character of the Committee's research program" brought about by the "success of the Whittle jet-propulsion engine". Staff working under Kervork Nahigyan in the special jet Propulsion Static Test Laboratory built and tested the first afterburner in October 1943, a direct result of the earlier work on the burner for Jake's jeep. Abe Silverstein's group adapted the Altitude Wind Tunnel to test the new jet propulsion units. General Electric and Westinghouse sent experimental models of their engines for tests in the new tunnel. Although denied work on their own experimental engine of NACA design, the staff of the Cleveland laboratory acquired a unique, hands on, experience in jet technology. They would build on this early experience to become the government's experts in jet propulsion in the early postwar years.

1 . Letter from Ben Pinkel to V. Dawson, 2 September 1984.

2 . Trip to England, 9 April-1 May 1941, Container 271, H. H. Arnold Papers, Manuscript Division, Library of Congress. Lord Beaverbrook's full name was William Maxwell Aitken Lord Beaverbrook.

3 . The best primary source for the history of the General Electric Whittle project is "Case History of Whittle Engine," Historical Study no. 93, Air Force Logistical Command History Office, Wright Patterson Air Force Base. This consists of Army correspondence and contains a wealth of information waiting to be mined. General Electric's company history, Seven Decades of Progress (Fallbrook, Calif.: Aero Publishers, Inc., 1979) is somewhat disappointing. An unpublished study by William Travers, The General Electric Aircraft Engine Story, is more detailed. General Electric Company papers from the West Lynn plant have recently been acquired by the National Air and Space Museum. "Jet Propulsion Engine Technical Data," Colonel Donald Keirn's Personal Data, Book, 1945, Part 1, Air Force Central Museum, Dayton, Ohio, includes the performances of all of the American turbojet projects.

4 . Statement by Dan Walker, An Encounter Between the jet Engine Inventors, Sir Rank Whittle and Dr. Hans von Ohain, 3-4 May 1978, History Office, Aeronautical Systems Division Air Force Systems Command, Wright-Patterson Air Force Base, Historical Publication,

5 . On turbosupercharger development, see Robert Schlaifer, Development of Aircraft Engines (Boston: Graduate School of Business Administration, Harvard University, 1950),p. 328-329. Also, Leslie E. Neville and Nathaniel F. Silsbee, jet Propulsion Progress: The Development of Aircraft Gas Turbines (New York: McGraw Hill, 1948), p. 98-102.

6 . Ben Pinkel, "Smoker Talk to AERL Staff," History looseleaf, NASA Lewis Records.

7 . Ben Pinkel to V. Dawson, 2 September 1984.

8 . A. H. R. Fedden, "Next Decade's Aero Engines Will Be Advanced But Not Radical." Transactions of the Society of Automotive Engineers 28(1933):379.

9 . Oscar W. Schey, Benjamin Pinkel, and Herman H. Ellerbrock, Jr., "Correction of Temperatures of Air-Cooled Engine Cylinders for Variation in Engine and Cooling Conditions," Technical Report 645, NACA 1939 Annual Report.

10 . Frank Whittle, "The Early History of the Whittle jet Propulsion Gas Turbine," Inst. Mech. Engr. Proceedings 152(1945):419.

11 . In addition to studies mentioned in note 5, for the history of jet propulsion, see Edward W. Constant II, The Origins of the Turbojet Revolution (Baltimore: The Johns Hopkins University Press, 1980). See also G. Geoffrey Smith, Gas Turbines and Jet Propulsion (London: Iliffe & Sons, 1955), 6th ed., and Walter J. Boyne and Donald S. Lopez, The Jet Age: Forty Years of Jet Aviation (Washington, D.C.: National Air and Space Museum, 1979).

12 . On the science-technology relationship, see Edwin Layton, "Mirror-Image Twins: The communities of science and technology in 19th-Century America." Technology and Culture 12:562-580.

13 . Edgar Buckingham, "Jet Propulsion for Airplanes," Technical Report 159, NACA 1923 Annual Report, p. 75-90. Buckingham's scheme probably consisted of a compressor with afterburner, the compressor driven by a reciprocating gasoline engine. (Comments courtesy of Hans von Ohain, 5 June 1987.) See also Rexmond C. Cochrane, Measures for Progress: A History of the National Bureau of Standards (U.S. Department of Commerce, 1966), p. 282-283.

14 . James Hansen, Engineer in Charge, NASA SP-4305, 1987, p. 225 and John Becker, The High-Speed Frontier , NASA SP-445 Washington, D.C.: US. Government Printing Office, 1980), p. 30.

15 . See Theodore von Karman's description of the conference in The Wind and Beyond (Boston: Little, Brown and Co., 1967), p. 216-218.

16 . "Walker, An Encounter Between the jet Engine Inventors, Sir Rank Whittle and Dr Hans von Ohain, p. 28.

17 . See Edward Constant's analysis, The Origins of the Turbojet Revolution, p. 15-18 and chapter 7. To an earlier draft of this chapter, Dr. Hans von Ohain responded by letter 5 June 1987: "I fully agree with you that the first success of jet engines was more a result of the simplicity of a radial jet engine with respect to structure, performance characteristics of the engine components and matching, rather than superior scientific insights in aerothermodynamics. (One could add that the radial engine also has inherently a favorable thrust to weight ratio, which is a necessary condition for high-speed flight.)"

18 . Hans von Ohain, "The Evolution and Future of Aeropropulsion Systems," in Boyne and Lopez, The Jet Age, p. 29.

20 . Interview with Hans von Ohain, 11 February 1985, at the National Air and Space Museum.

21 . Bush to Arnold, 2 July 1941, 47/208, Papers of H. H. Arnold, Manuscript Division, Library of Congress. On the Tizard mission, see Daniel J. Kevies, The Physicists (New York: Vantage Books, 1979), p. 302-303.

22 . Arnold to Bush, 25 February 1941, Records of NACA Committees and Subcommittees, National Archives, Record Group 255, 117.15. On the rocket work of the Guggenheim Aeronautical Laboratory, California Institute of Technology, see also Clayton Koppes, The JPL and the American Space Program (New Haven: Yale University Press, 1982).

23 . Kevies, The Physicists, p. 296.

24 . Bush to Arnold, 10 March 1941, Records of NACA Committees and Subcommittees, National Archives, Record Group 255, 117.15.

25 . Towers to Bush, 17 March 1941, NACA Committees and Subcommittees, National Archives, Record Group 255, 117.15.

26 . Frank B. Jewett, President of the National Academy of Science, on the occasion of Durand's 85th birthday, National Archives, Record Group 255, Durand biographical file. See also Walter G. Vincenti, "The Air-Propeller Tests of W. R Durand and E. R Lesley: A Case Study in Technological Methodology." Technology and Culture 20:712-751.

27 . Bush to Durand, 18 March 1941, Records of Committees and Subcommittees, National Archives, Record Group 225, 117.15.

28 . Ibid. This opinion was also shared by Towers. See Tower's letter to Bush, 17 March 1941, and Bush to Charles Abbot, 29 March 1941, National Archives, Record Group 225. The full committee consisted of Durand, Soderberg, R. C. Allen (Allis-Chalmers), L. W. Chubb (Westinghouse), A. G. Christie, Hugh L. Dryden, Brig. Gen. 0. P. Echols, Jerome Hunsaker (ex officio), Capt. S. M. Kraus, U.S.N., G. W. Lewis (ex officio), and A. R. Stevenson, Jr. (General Electric).

29 . L. S. Hobbs to Jerome Hunsaker, 12 December 1941, NASA History Office, Washington, D.C., copied from J. C. Hunsaker Papers, Smithsonian Institution. See also Schlaifer, Development of Aircraft Engines, p. 453.

30. Minutes of Meeting of Special Committee on jet Propulsion, 10 April 1941, NASA History Office. My discussion relies on the minutes of the Special Committee April 10, 22, May 2, 8, 28 (July 25 missing) Compressor-Turbine Panel: July 25, September 22, 1941, February 3, 1942 Compressor-Turbine Panel, February 3, 1942, July 31, 1942, and December 1, 1942, located in the NASA History Office. Minutes of February 20, 1942, July 31, 1942, April 2, 1943, August 18, 1943, October 29, 1943 are in National Archives, Record Group 225. See also correspondence and Durand's reports in Records of NACA Committees and Subcommittees, National Archives, Record Group 225, 117.15. My account is supplemented by correspondence between Bush, Durand, and Arnold found in H. H. Arnold Papers, Manuscript Division, Library of Congress. For information on the Westinghouse project, I have also consulted the New Papers and the Westinghouse file, National Air and Space Musuem, Washington, D.C. Goddard's rocket work is compared to the far more practical work of the group at the California Institute of Technology by Clayton Koppes, JPL and the American Space Program New Haven: Yale University Press, 1982), chapter 1.

31 . Bush to Durand, 18 March 1941, Records of Committees and Subcommittees, National Archives, Record Group 225, 117.15.

32 . James Hansen has shed new light on the NACA project at Langley in Engineer in Charge, chapter 8. Hansen's account relies on extensive documents in the Langley archives. See also Brian J. Nichelson, "Early jet Engines and the Transition from Centrifugal to Axial Compressors: A Case Study in Technological Change," Ph.D. Dissertation, University of Minnesota, 1988. The work of the Durand committee is discussed briefly in Schlaifer, The Development of Aircraft Engines, p. 457-460. The Jacobs project received only a passing reference in George Gray's Frontiers of Flight (New York: Alfred A. Knopf, 1948), p. 278, a work commissioned by the NACA. For a reliable account of early jet propulsion work in Europe and the United States, see Leslie E. Neville and Nathaniel F Silsbee, jet Propulsion Progress (New York: McGraw-Hill, 1948).

33 . In a letter to the author, Ben Pinkel wrote, 2 September 1984:

Jacobs enlisted the aid of Eugene Wasielewski (a member of the Supercharger Section of the Power Plant Division) in the design of the compressor, and it proved to provide good performance. They built a vaporizing type burner for this system on the assumption that vaporization of the fuel was required to achieve efficient combustion.

Jacobs could not get the burner to function properly. The "jeep," as this system was called, was turned over to the Engine Analysis Section for further development and testing. I assigned K. K. (Nick) Nahigyan the task of designing the burner. He employed about 40 spray type liquid injection nozzles each located at the apex of individual bell-shaped shells. The bells were oriented with their open ends down-stream and served as flame holders.

The engine cycle consisted of the following steps. Air entered the front of the nacelle, was compressed by the engine-driven compressor, then passed into the combustion chamber where fuel was injected and ignited and finally, the products were discharged through the variable area nozzle.

34 . Clinton E. Brown to V. Dawson, 11 September 1989. On the ducted fan, see James Hansen, Engineer in Charge, p. 222. See also Jonathan W. Thompson, Italian Civil and Military Aircraft 1930-1945 (Fallbrook, Calif.: Aero Publishing, 1963), p. 95-96.

35 . Macon C. Ellis, Jr., and Clinton E. Brown, "NACA Investigation of a Jet-Propulsion System Applicable to Flight." Technical Report 802, NACA 1943 Annual Report, p. 491-501. This is the only published NACA report on the jeep.

36 . Durand to Arnold, 9 May 1941, 43/102, Manuscript Division, Library of Congress. The work of Hayne Constant and A. A. Griffith led to an agreement in 1937 between the Royal Aircraft Establishment and Metropolitan Vickers Company to design an engine with an axial compressor. This engine was flight tested 13 November 1943. For further information on the development of British turbojet engines, see Harold Roxbee Cox, "The Beginnings of jet Propulsion." The Royal Society of Arts Journal, September 1985, p. 705-723.

37 . Minutes of the Special Committee on jet Propulsion, 8 May 1941, p. 4, NASA History Office. The report on Jacobs's compressor work was published after he left Langley by John T. Sinnette, Jr., Oscar W. Schey, and J. Austin King, "Performance of NACA Eight-Stage Axial-Flow Compressor Designed on the Basis of Airfoil Theory," Technical Report 758, NACA 1943 Annual Report. For a case study of early axial-compressor development, see Brian J. Nichelson, "Early jet Engines and the Transition from Centrifugal to Axial Compressors: A Case Study in Technological Change," Ph.D. Dissertation, University of Minnesota, 1988.

38 . Arnold to Bush, 2 June 1941, Picture and description have no date and were separated from the memo routed from Bush to Durand and then returned. H. H. Arnold Papers, 47/208, Manuscript Division, Library of Congress.

39 . Arnold to Bush, 25 June 1941, H. H. Arnold Papers, 44/124, Manuscript Division, Library of Congress.

40 . Bush to Arnold, 2 July 1941, H. H. Arnold Papers, 47/208, Manuscript Division, Library of Congress.

41 . Bush to Arnold, 11 July 1941, H. H. Arnold Papers, 471208, Manuscript Division, Library of Congress.

42 Arnold to Alfred J. Lyon, 2 October 1941, H. H. Arnold Papers, 43/102, Manuscript Division, Library of Congress.

43 . Minutes of Meeting of Turbine Panel of jet Propulsion Committee, 25 July 1941, p. 2, NASA History Office. A company history of General Electric, Seven Decades of Progress (Fallbrook, Calif.: Aero Publishers, 1979), p. 41, says that by June all three companies were committed to the axial compressor.

44 . Alan Howard, who worked on General Electric's turboprop, the TG-100, based his design for an axial-flow compressor on a 1934 NACA paper by O'Brien and Folsom, "the Design of Propeller Pumps and Fans." He gave the specifications based on data relating to airflow over a NACA airfoil to the Peerless Pump Company (now part of Food Machinery Corporation) "with the proviso that the pump be built exactly to the design calculations." Letter to the author from William Travers, 22 August 1985. However, a G.E. company history relates that Howard, Glenn Warren, and Bruce Buckland, who worked on the project, were convinced by tests of an axial compressor carried out in Cleveland, undoubtedly a reference to the eight-stage axial compressor, tested in Cleveland and used in the TG-180, a turbojet designed after the TG-100. See Seven Decades of Progress, p. 39. See also A. R. Stevenson to Durand, 27 November 1942, NACA Committees and Subcommittees, National Archives, Record Group 225, 117.15.

45 . Neville and Silsbee, Jet Propulsion Progress, p. 147. The Brown-Boveri compressor, mentioned in the WR. New Papers, National Air and Space Museum, may have been the basis for their compressor design. See also Kroon to Durand, 24 April 1944, Records of NACA Committees and Subcommittees, National Archives, Record Group 225, 117.15

46 . Minutes of the Executive Committee of the NACA, 24 October 1941, National Archives, Record Group 225, Box 8.

47 . Durand to Echols, 27 February 1942, Records of NACA Committees and Subcommittees, National Archives, Record Group 225, 117.15.

48 . "Case History of Whittle Engine," Historical Study no. 93, vol. I, document 24, AFLC History Office, Wright-Patterson Air Force Base, Dayton, Ohio. Classification of the Whittle project was downgraded from "supersecret" to "secret" in summer 1943.

49 . Minutes of the Executive Committee of the NACA, 16 June 1942, National Archives, Record Group 225, Box 8.

50 . A. R. Stevenson to Durand, 27 November 1942, NACA Committees and Subcommittees, National Archives, Record Group 225, 117.15.

51 . For the development of the Westinghouse "Yankee" engine, see "The History of Westinghouse in the War," Aviation Gas Turbine Division, Engineering Department, Westinghouse, in the W, R. New Papers, Special Collections of Air and Space Museum, Washington, D.C., p. 20. Charles Edward Chapel, ed., Aircraft Power Plants ed, New York: McGraw-Hill, 1948), p. 353-363, See also Neville and Silsbee, Jet Propulsion Progress, p. 145-50 John Foster, Jr., "Design Analysis of Westinghouse 19-B Turbojet." Aviation, January 1946, p. 60-68 Robert B. Meyer, Jr. "Classic Turbine Engines," in Casting About (Howmet Turbine Components Corp. magazine, 1985), p, 12-15.

52 . Neville and Silsbee, Seven Decades of Progress, p. 55. Arnold authorized discussion "of the Whittle matter" with Glenn Warren, one of G.E's designers at Schenectady. Arnold to D. R. Shoults, 27 August 1941, reproduced in Seven Decades of Progress, p. 45.

53 . Durand's "Notes on Visit to Langley Field," 31 March 1942, and Minutes of Executive Committee of NACA, 16 June 1942, National Archives, Record Group 255, Box 8 Ben Pinkel to author, 26 October 1984.

54 . Durand to Lewis, 29 September 1942, National Archives, Group Record 255, 117.15.

55 . Durand to Stevenson, 16 October 1942 Durand to Keirn, 29 October 1942, National Archives, Record Group 255, 117.15. Hansen discusses the continuation of the Campini project, in Engineer in Charge, p. 238-247.

56 . Durand to Members of Special Committee on jet Propulsion: Soderberg, Allen, Chubb, Christie, Dryden, Keirn, Kraus, Spangler, Stevenson, Taylor, 6 November 1942, Records of NACA Committees and Subcommittees, National Archives, Record Group 255, 117.15.

57 . Letter to V. Dawson, 2 September 1984. Pinkel did not give the author an exact date. Arnold's letter to the NACA informing it of his decision to fight the war with the piston engine is dated 14 October 1942. It was reported in the Minutes of the Power Plants Committee, 11 December 1942, Records of NACA Committees and Subcommittees, National, Archives, Record Group 255, 112.02. This seems consistent with Pinkel's recollection that he heard of Arnold's decision prior to his departure for Cleveland. It is not entirely clear what tests on the jeep he is referring to here.

58 . Pinkel to V. Dawson, 2 September 1984. A sketch of Nahigyan's design can be found in Records of NACA Committees and Subcommittees, National Archives, Record Group 255, 117.15.

59 . Memorandum for files, "Visit to Wright Field to discuss NACA jet-propulsion airplane design," 20 January 1943, Jacobs file, National Archives, Record Group 255, Box 131, 23-25.

60 . Minutes of Meeting of Special Committee on jet Propulsion, 2 April 1943, National Archives, Record Group 255, 117.15.

61 . Roland, Model Research, p. 185.

62 . Arnold to Craig, "Defense Against Enemy jet Propelled Aircraft," 24 May 1944, Papers of H. H. Arnold, Carton 43, file 102, Manuscript Division, Library of Congress. See also I. B. Holley, Jr., "Jet Lag in the Army Air Corps," Military Planning in the Twentieth Century, Proceedings of the Eleventh Military History Symposium, 10-12 October 1984, Office of Air Force History, p. 123-153.

63 . Minutes of Meeting of Special Committee on jet Propulsion, 18 August 1943, National Archives, Record Group 255, 11.

64 . Telephone conversation with Henry Meltzer, 17 September 1984. Meltzer later became head of the turbine blade section. Also interview with Rudy Beheim, 11 July 1984.

65 . Report to the Executive Committee, 16 March 1944, NACA Executive Committee Minutes, National Archives, Record Group 255, Box 9.


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