General Electric I-A

I-A
Type	Turbojet
National origin	United States
Manufacturer	General Electric
First run	April 18, 1942
Number built	30
Developed from	Power Jets W.2B/23
Developed into	General Electric J31

Last updated January 10, 2024

The General Electric I-A was the first working jet engine in the United States, manufactured by General Electric (GE) and achieving its first run on April 18, 1942.

Design and development

Front view of the preserved Power Jets W.1 at the Science Museum (London) The almost identical W.1X is preserved at the Smithsonian Institution, Washington, DC. PowerJetsW.1.JPG — Front view of the preserved Power Jets W.1 at the Science Museum (London) The almost identical W.1X is preserved at the Smithsonian Institution, Washington, DC.

During the late 1930s/early 1940s, a small company in England, known as Power Jets, had been developing, through a series of prototypes, a gas turbine engine to provide aircraft jet propulsion. Power Jets had been started by a Frank Whittle, who had thought of the concept of a jet engine whilst he was a young flight cadet at RAF Cranwell.^[3] He applied for a patent for the engine in January, 1930, although he eventually allowed the patent to lapse.

Power Jets Ltd was formed in March 1936. Manufacture of key engine components was undertaken by the British Thomson-Houston Company (BTH), starting in June 1936. Testing of the first engine, the WU, to demonstrate the concept, commenced on April 12, 1937. Because of a shortage of funds at Power Jets, engine components were in short supply, so development proceeded at a very slow pace.

However, in the summer of 1939, shortly before war was declared, the Air Ministry suddenly realised that the jet engine was likely to become a viable means of propulsion. As a result, Power Jets received a contract for a flight engine on July 12, 1939. Shortly afterwards, a contract was placed with Gloster Aircraft Company to produce an experimental aircraft to demonstrate the engine.

In May 1941, the first British jet aircraft, Gloster E.28/39, made its maiden flight. It was powered by the 860 lbf (3.8 kN) thrust Power Jets W.1. Prior to this first flight another engine known as the W.1X had been used in the prototype aircraft for taxiing trials. This particular one-off engine had been assembled from a collection of spare parts and was not considered flightworthy.

After a visit to England mid-1941, General Henry H. Arnold was so impressed by flight demonstrations of the Gloster E.28/39 he had witnessed that he arranged for the Whittle W.1X turbojet engine to be flown in October 1941 to the U.S in the bomb bay of a USAAC Consolidated B-24 Liberator,^[4] along with drawings for the more powerful W.2B/23 engine and a small team of Power Jets engineers,^[5] so that the US could develop its own jet engine. As a result, General Electric received a contract from U.S Army Air Corps to build a turbojet based on the W.2B/23.^[6] General Electric's extensive experience in turbocharger production made them the natural choice for producing such engine.^[7] With utmost secrecy, in October 1941 a small dedicated GE team at Lynn, Massachusetts, began the intensive development of the first US jet engine. GE initially referred to their engine as the Type I.^[8] Engine component production was undertaken fairly openly, but the project reference "Type I Supercharger" was used to disguise the true application of the parts.^[9]

The aerodynamic design and many mechanical features of the Type I were identical to that of the W.2B/23. However, there were some major differences, principally with the design of the wheelcase, which was brought into line with the US practice of mounting engine accessories on the engine itself.^[10]

In November 1941, well before the Type I would become available for testing, General Electric started ground running of the Power Jets W.1X engine.^[11] This was the first jet engine to run on US soil, but more importantly GE gained valuable experience of testing a turbojet engine.

On April 18, 1942, twenty-eight weeks after stateside work began, GE's engineers successfully ran the first Type I engine. True, the unit stalled before full engine speed was obtained, but this reflected British experience with the W.2B.

With their vast experience of developing turbochargers, General Electric turned their expertise to improving the Type I. A modified version, the Type I-A, incorporating partitions in the blower casing to separate the air flow into each of the individual combustion chambers at the suggestion of Whittle,^[12] began testing on May 18, 1942, and developed a thrust of 1,250 lbf (5.6 kN), at an overall pressure ratio of 3:1.

On October 1, 1942, a Bell XP-59A aircraft, powered by two 1,250 lbf thrust I-A turbojet engines, made its first flight at the Muroc Army Air Field in California. Further engine developments produced a 1,400 lbf (6.2 kN) thrust engine, known as the I-14, which was used to propel the service test YP-59A aircraft.

Ultimately, General Electric found they could produce a thrust of 1,610 lbf (7.2 kN) from a package the same size and weight as the I-A, which they called the I-16.^[13] Later, when the P-59 went into production, the aircraft was fitted with J31s, which was the USAAF designation for the I-16.

Meanwhile, Power Jets continued to develop the W.2B, initially with the help of the Rover Company. On April 1, 1943, Rolls-Royce took responsibility for developing the engine, and it went into small-scale production as the 1,600 lbf thrust Rolls-Royce Welland I in October, 1943. The Gloster Meteor I fighter, which entered RAF service in July, 1944, was powered by the Welland I.

Variants

Type I

Initial design based on W.1X. Incorporated automatic control system and forged Hastelloy B turbine blades. First run on 18th April 1942.

Type I-A

Revised design incorporating partitions in blower casing at suggestion of Whittle.^[14]

Engines on display

The W.1X is on display at the Smithsonian Institution, Washington DC.^[15]

I-1A on display at Valiant Air Command - Titusville Florida

Applications

Bell XP-59A

Specifications (General Electric I-A)

General characteristics

Type: Centrifugal compressor turbojet, single shaft
Length: 70.5 in (1791mm)
Diameter: 44 in (1118mm)
Dry weight: 780lb (354kg)^[16]

Components

Compressor: Single-stage double-sided centrifugal
Combustors: 10 reverse-flow can
Turbine: Single-stage axial
Fuel type: Kerosene

Performance

Maximum thrust: 1,250 lbf (5.6 kN)
Overall pressure ratio: 3:1
Thrust-to-weight ratio: 1.6

Related Research Articles

A jet engine is a type of reaction engine, discharging a fast-moving jet of heated gas that generates thrust by jet propulsion. While this broad definition may include rocket, water jet, and hybrid propulsion, the term jet engine typically refers to an internal combustion air-breathing jet engine such as a turbojet, turbofan, ramjet, pulse jet, or scramjet. In general, jet engines are internal combustion engines.

Air Commodore Sir Frank Whittle, was an English engineer, inventor and Royal Air Force (RAF) air officer. He is credited with having invented the turbojet engine. A patent was submitted by Maxime Guillaume in 1921 for a similar invention which was technically unfeasible at the time. Whittle's jet engines were developed some years earlier than those of Germany's Hans von Ohain, who designed the first-to-fly turbojet engine.

The turbojet is an airbreathing jet engine which is typically used in aircraft. It consists of a gas turbine with a propelling nozzle. The gas turbine has an air inlet which includes inlet guide vanes, a compressor, a combustion chamber, and a turbine. The compressed air from the compressor is heated by burning fuel in the combustion chamber and then allowed to expand through the turbine. The turbine exhaust is then expanded in the propelling nozzle where it is accelerated to high speed to provide thrust. Two engineers, Frank Whittle in the United Kingdom and Hans von Ohain in Germany, developed the concept independently into practical engines during the late 1930s.

The Gloster E.28/39, was the first British turbojet-engined aircraft first flying in 1941. It was the third turbojet aircraft to fly after the German Heinkel He 178 (1939) and the German Heinkel He 280 (1941).

The Bell P-59 Airacomet was a single-seat, twin jet-engine fighter aircraft that was designed and built by Bell Aircraft during World War II. It was the first jet produced in the United States. As the British were further along in jet engine development, they donated an engine for the United States to copy in 1941 that became the basis for the General Electric J31 jet engine used by the P-59 a year later. Because the plane was underpowered, the United States Army Air Forces (USAAF) was not impressed by its performance and canceled half of the original order for 100 fighters, using the completed aircraft as trainers. The USAAF would instead go on to select the Lockheed P-80 Shooting Star as its first operational jet fighter. Although no P-59s entered combat, the aircraft paved the way for later generations of U.S. turbojet-powered aircraft.

The Rolls-Royce RB.41 Nene is a 1940s British centrifugal compressor turbojet engine. The Nene was a complete redesign, rather than a scaled-up Rolls-Royce Derwent, with a design target of 5,000 lbf (22 kN), making it the most powerful engine of its era. First run in 1944, it was Rolls-Royce's third jet engine to enter production, and first ran less than 6 months from the start of design. It was named after the River Nene in keeping with the company's tradition of naming its jet engines after rivers.

The General Electric/Allison J35 was the United States Air Force's first axial-flow compressor jet engine. Originally developed by General Electric in parallel with the Whittle-based centrifugal-flow J33, the J35 was a fairly simple turbojet, consisting of an eleven-stage axial-flow compressor and a single-stage turbine. With the afterburner, which most models carried, it produced a thrust of 7,400 lbf (33 kN).

The Rolls-Royce RB.37 Derwent is a 1940s British centrifugal compressor turbojet engine, the second Rolls-Royce jet engine to enter production. It was an improved version of the Rolls-Royce Welland, which itself was a renamed version of Frank Whittle's Power Jets W.2B. Rolls-Royce inherited the Derwent design from Rover when they took over their jet engine development in 1943.

The Rolls-Royce RB.23 Welland was Britain's first production jet engine. It entered production in 1943 for the Gloster Meteor. The name Welland is taken from the River Welland, in keeping with the Rolls-Royce policy of naming early jet engines after rivers based on the idea of continuous flow, air through the engine and water in a river.

This article outlines the important developments in the history of the development of the air-breathing (duct) jet engine. Although the most common type, the gas turbine powered jet engine, was certainly a 20th-century invention, many of the needed advances in theory and technology leading to this invention were made well before this time.

The Metropolitan-Vickers F.2 is an early turbojet engine and the first British design to be based on an axial-flow compressor. It was an extremely advanced design for the era, using a nine-stage axial compressor, annular combustor, and a two-stage turbine.

The de Havilland Goblin, originally designated as the Halford H-1, is an early turbojet engine designed by Frank Halford and built by de Havilland. The Goblin was the second British jet engine to fly, after Whittle's Power Jets W.1, and the first to pass a type test and receive a type certificate issued for an aircraft propulsion turbine.

The General Electric J47 turbojet was developed by General Electric from its earlier J35. It first flew in May 1948. The J47 was the first axial-flow turbojet approved for commercial use in the United States. It was used in many types of aircraft, and more than 30,000 were manufactured before production ceased in 1956. It saw continued service in the US military until 1978. Packard built 3,025 of the engines under license.

The General Electric J85 is a small single-shaft turbojet engine. Military versions produce up to 2,950 lb_f (13.1 kN) of thrust dry; afterburning variants can reach up to 5,000 lb_f (22 kN). The engine, depending upon additional equipment and specific model, weighs from 300 to 500 pounds. It is one of GE's most successful and longest in service military jet engines, with the civilian versions having logged over 16.5 million hours of operation. The United States Air Force plans to continue using the J85 in aircraft through 2040. Civilian models, known as the CJ610, are similar but supplied without an afterburner and are identical to non-afterburning J85 variants, while the CF700 adds a rear-mounted fan for improved fuel economy.

The General Electric/Allison J33 is an American centrifugal-flow jet engine, a development of the General Electric J31, enlarged to produce significantly greater thrust, starting at 4,000 lbf (18 kN) and ending at 4,600 lbf (20 kN) with an additional low-altitude boost to 5,400 lbf (24 kN) with water-alcohol injection.

The General Electric J31 was the first jet engine to be mass-produced in the United States.

<span class="mw-page-title-main">Power Jets</span> Defunct British jet engine manufacturer

Power Jets was a British company set up by Frank Whittle for the purpose of designing and manufacturing jet engines. The company was nationalised in 1944, and evolved into the National Gas Turbine Establishment.

The Power Jets W.1 was a British turbojet engine designed by Frank Whittle and Power Jets. The W.1 was built under contract by British Thomson-Houston (BTH) in the early 1940s. It is notable for being the first British jet engine to fly, as the "Whittle Supercharger Type W1", powering the Gloster E.28/39 on its maiden flight at RAF Cranwell on 15 May 1941. The W.1 was superseded by the Power Jets W.2.

The Power Jets W.2 was a British turbojet engine designed by Frank Whittle and Power Jets Ltd. Like the earlier Power Jets W.1, the reverse-flow combustion configuration included a double-sided centrifugal compressor, 10 combustion chambers and an axial-flow turbine with air-cooled disc. It entered production as the Rolls-Royce Welland and was the first UK jet engine to power operational aircraft, the Gloster Meteor.

The Power Jets WU was a series of three very different experimental jet engines produced and tested by Frank Whittle and his small team in the late 1930s.

References

↑ "Aviation History | GE Aviation".
↑ Eight Decades of Progress : A Heritage of Aircraft Turbine Technology. GE Aircraft Engines. 1990. p. 54. LCCN 90082948.
↑ "Archived copy". Archived from the original on 2016-03-05. Retrieved 2016-04-09.{{cite web}}: CS1 maint: archived copy as title (link)
↑ http://web.itu.edu.tr/aydere/history.pdf ^{[ bare URL PDF ]}
↑ "Archived copy". Archived from the original on 2016-04-27. Retrieved 2016-04-16.{{cite web}}: CS1 maint: archived copy as title (link)
↑ "Whittle W.2B Archives". October 2023.
↑ "W2B: US vs UK Development". Archived from the original on 2016-03-30. Retrieved 2016-04-09.
↑ "G.E. Engineers Test Jet Engine". 18 April 2008.
↑ Bell P-59 Airacomet Development. YouTube . Archived from the original on 2021-12-09.
↑ "R-R W2B". Archived from the original on 2014-05-07. Retrieved 2016-04-09.
↑ Pace, Steve (2016-03-15). The Big Book of X-Bombers & X-Fighters: USAF Jet-Powered Experimental Aircraft and Their Propulsive Systems. Zenith Press. ISBN 9780760351420.
↑ "World Encyclopedia of Aero Engines - 5th edition" by Bill Gunston, Sutton Publishing, 2006, p.80
↑ Jenkins, Dennis R.; Pyeatt, Don (2008-04-30). Experimental and Prototype U.S. Air Force Jet Fighters. Specialty Press. ISBN 9781580071116.
↑ "World Encyclopedia of Aero Engines - 5th edition" by Bill Gunston, Sutton Publishing, 2006, p.80
↑ "Archived copy". Archived from the original on 2016-05-13. Retrieved 2016-04-12.{{cite web}}: CS1 maint: archived copy as title (link)
↑ "General Electric J79".

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[1] "Aviation History | GE Aviation".

[2] Eight Decades of Progress : A Heritage of Aircraft Turbine Technology. GE Aircraft Engines. 1990. p. 54. LCCN 90082948.

[3] "Archived copy". Archived from the original on 2016-03-05. Retrieved 2016-04-09.{{cite web}}: CS1 maint: archived copy as title (link)

[4] ttp://web.itu.edu.tr/aydere/history.pdf ^{[ bare URL PDF ]}

[5] "Archived copy". Archived from the original on 2016-04-27. Retrieved 2016-04-16.{{cite web}}: CS1 maint: archived copy as title (link)

[6] "Whittle W.2B Archives". October 2023.

[7] "W2B: US vs UK Development". Archived from the original on 2016-03-30. Retrieved 2016-04-09.

[8] "G.E. Engineers Test Jet Engine". 18 April 2008.

[9] Bell P-59 Airacomet Development. YouTube . Archived from the original on 2021-12-09.

[10] "R-R W2B". Archived from the original on 2014-05-07. Retrieved 2016-04-09.

[11] Pace, Steve (2016-03-15). The Big Book of X-Bombers & X-Fighters: USAF Jet-Powered Experimental Aircraft and Their Propulsive Systems. Zenith Press. ISBN 9780760351420.

[12] "World Encyclopedia of Aero Engines - 5th edition" by Bill Gunston, Sutton Publishing, 2006, p.80

[13] Jenkins, Dennis R.; Pyeatt, Don (2008-04-30). Experimental and Prototype U.S. Air Force Jet Fighters. Specialty Press. ISBN 9781580071116.

[14] "World Encyclopedia of Aero Engines - 5th edition" by Bill Gunston, Sutton Publishing, 2006, p.80

[15] "Archived copy". Archived from the original on 2016-05-13. Retrieved 2016-04-12.{{cite web}}: CS1 maint: archived copy as title (link)

[16] "General Electric J79".

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v t e General Electric Aircraft Engines/GE Aviation/GE Aerospace aircraft engines
Turbojets	CJ610 CJ805 GE1 GE4/J5 I-A J31 J33 J35 J47 J73 J79 J85 J87 YJ93 J97 YJ101
Turbofans	Affinity CF6 CF34 CF700 CFE738† CFM56† CJ805-23 F101 F108† F110 F118 YF120 F136† F404/F412 F414 GE90 GE9X GEnx GP7000† HF120† LEAP† Passport RM12† TF34 TF39 XA100
Turboprops/Turboshafts	Catalyst CT7 CT58 CT64 GE27 GE38 H-Series T31 T58 T64 T407 T408 T700 T901
Aeroderivative gas turbine engines	LM500 LM1500 LM1600 LM2500 LM6000 LM9000 LMS100
Propfans	GE36 RISE†
Key people	Gerhard Neumann
† Joint development aeroengines

v t e United States military gas turbine aircraft engine designation system
Turbojets	J30 J31 J32 J33 J34 J35 J36 J37 XJ38 J39 J40 XJ41 J42 J43 J44 J45 J46 J47 J48 XJ49 J51 J52 J53 J54 J55 J56 J57 J58 J59 J60 J61 J63 J65 J67 J69 J71 J73 J75 J79 J81 J83 J85 J87 J89 J91 YJ93 J95 J97 J99 J100 YJ101 J102 J400 J401 J402 J403 J700
Turboprops/ Turboshafts	T30 T31 T33 T34 T35 T36 T37 T38 T39 T40 T41 T42 T43 T44 T45 T46 T47 T48 T49 T50 T51 T52 T53 T54 T55 T56 (variants) T57 T58 T60 T61 T62 T63 T64 T65 T66 T67 T68 T69 T70 T71 T72 T73 T74 T76 T78 T80 T100 T101 T400 T405 T406 T407 T408 T700 T701 T702 T703 T706 T708 LHTEC T800 APW T800 T900 T901
Turbofans	TF30 TF31 TF32 TF33 TF34 TF35 TF37 TF39 TF41 F100 F101 F102 F103 F104 F105 F106 F107 F108 F109 F110 F112 F113 F117 F118 F119 YF120 F121 F122 F124 F125 F126 F127 F128 F129 F130 F135 F136 F137 F138 F400 F401 F402 F404 F405 F408 F412 F414 F415
Adaptive cycle engines	XA100 XA101