Early efforts

General Electric had a long history in steam turbine work, dating back to the 1900s. In 1903 they hired Sanford Alexander Moss, who started the development of turbosuperchargers at GE. This led to a series of record-breaking flights over the next ten years. At first, the role of the high-altitude flight was limited, but in the years immediately prior to WWII they became standard equipment on practically all military aircraft. GE was a world leader in this technology; most other firms concentrated on the mechanically simpler supercharger driven by the engine itself, while GE had spent considerable effort developing the exhaust-driven turbo system that offered higher performance.

This work made them the natural industrial partner to develop jet engines when Frank Whittle's W.1 engine was demonstrated to Hap Arnold in 1941.^[8] A production license was arranged in September, and several of the existing W.1 test engines shipped to the US for study, where they were converted to US manufacture as the I-A. GE quickly started production of improved versions; the I-16 (J31) was produced in limited numbers starting in 1942, and the much more powerful I-40 (J33) followed in 1944, which went on to power the first US combat-capable jet fighters, the P-80 Shooting Star.

Early jet engine work took place at GE's Syracuse, New York, (steam turbine) and Lynn, Massachusetts, (supercharger) plants, but soon concentrated at the Lynn plants.^[9] On 31 July 1945 the Lynn plant became the "Aircraft Gas Turbine Division". GE was repeatedly unable to deliver enough engines for Army and Navy demand, and production of the I-40 (now known as the J33) was also handed to Allison Engines in 1944. After the war ended, the Army canceled its orders for GE-built J33s and turned the entire production over to Allison,^[10] and the Syracuse plant closed.

Military and civilian expansion

These changes in fortune led to debate within the company about carrying on in the aircraft engine market. However, the engineers at Lynn pressed ahead with the development of a new engine, the TG-180, which was designated J35 by the US military.^[11]

Development funds were allotted in 1946 for a more powerful version of the same design, the TG-190. This engine finally emerged as the famed General Electric J47, which saw a great demand for several military aircraft; a second manufacturing facility in Evendale, Ohio, near Cincinnati, was opened. J47 production ran to 30,000 engines by the time the lines closed down in 1956. Further development of the J47 by Patrick Clarke in 1957 led to the J73, and from there into the much more powerful J79. The J79 was GE's second "hit", leading to a production run of 17,000 in several different countries. The GE and Lockheed team that developed the J79 and the F-104 Mach 2 fighter aircraft received the 1958 Collier Trophy for outstanding technical achievement in aviation. Other successes followed, including the T58 and T64 turboshaft engines, the J85 turbojet, and F404 turbofan.

Starting in 1961, General Electric started one of their most important research and development efforts, the GE1 technology demonstrator (originally designated the X101). The GE1 was a basic gas generator (compressor, combustor and turbine) onto which a variety of components such as fans, afterburners or other thrust vectoring devices could be added later. The design incorporated technologies such as a scaled compressor with variable stator vanes, an annual combustor, turbine-cooling advancements, and new materials for several government research programs. The US Government initially supported development of the GE1 to produce the J97 engine. The GE1 design and technology helped General Electric produce a range of engines, including the GE1/6 turbofan demonstrator for the TF39 engine the GE4 for the Boeing 2707 supersonic airliner, and the GE9 engine for the USAF's Advanced Manned Strategic Aircraft, later GE F101 engines for the B-1 bomber.^[12]:^[13] The General Electric F101 was later developed into the General Electric F110 and CFM International CFM56 engines.

The TF39 was the first high-bypass turbofan engine to enter production.^[14] Entered into the C-5 Galaxy contest in 1964 against similar designs from Curtiss-Wright and Pratt & Whitney, GE's entry was selected as the winner during the final down-select in 1965. This led to a civilian model, the CF6,^[15] which was offered for the Lockheed L-1011 and McDonnell Douglas DC-10 projects. Although Lockheed later changed their engine to the Rolls-Royce RB211, the DC-10 continued with the CF6, and this success led to widespread sales on many large aircraft including the Boeing 747.

Another military-to-civilian success followed when GE was selected to supply engines for the S-3 Viking and Fairchild Republic A-10 Thunderbolt II, developing a small high-bypass engine using technologies from the TF39. The resulting TF34 was adapted to become the CF34, whose wide variety of models powers many of the regional jets flying today.^[16]

In the early 1970s, GE was also selected to develop a modern turboshaft engine for helicopter use, the T700. It has been further developed as the CT7 turboprop engine for regional transports.

Commercial aviation powerplants

In 1974 GE entered into an agreement with Snecma of France, forming CFM International to jointly produce a new mid-sized turbofan, which emerged as the CFM56. A 50/50 joint partnership was formed^[17] with a new plant in Evendale, OH to produce the design. At first, sales were very difficult to come by, and the project was due to be canceled. Only two weeks before this was to happen, in March 1979, several companies selected the CFM56 to re-engine their existing Douglas DC-8 fleets.^[18] By July 2010, CFM International had delivered their 21,000th engine of the CFM56 family, with an ongoing production rate of 1250 per year, against a four-year production backlog.^[19]

The success of the CFM led GE to join in several similar partnerships, including Garrett AiResearch for the CFE CFE738, Pratt & Whitney on the Engine Alliance GP7000, and, more recently, Honda for the GE Honda Aero Engines small turbofan project. GE also continued the development of its own lines, introducing new civilian models like the GE90, and military designs like the General Electric F110.

GE Aviation today

Then-GEAE (and competitor Rolls-Royce) were selected by Boeing to power its new 787. GE Aviation's offering is the GEnx, a development of the GE90. GE Aviation also has a two-year exclusivity on the Boeing 747-8.

The Lynn facility continues to assemble jet engines for the United States Department of Defense, subsidiary services, and commercial operators. Engines assembled at this plant include the F404, F414, T700, and CFE738. The plant at Lynn also produces the -3 and -8 variants of the CF34 regional jet engine, the CT7 commercial turboprop power plant, and commercial versions of the T700 turboshaft which are also called the CT7.

The Evendale plant conducts final assembly for the CFM International's CFM56, CF6, as well as LM6000, and LM2500 power plants.

The Durham, North Carolina, facility conducts final assembly for the LEAP-X, GEnx, CFM56, GE90, GP7200, and CF34 power plants. Crucial parts for these engines are crafted in secondary GE Aviation facilities, such as those in Bromont, Quebec; Hooksett, New Hampshire; Wilmington, North Carolina; Madisonville, Kentucky; Rutland, Vermont; and Muskegon, Michigan; where the engine blades and vanes are manufactured.

Smiths Group and General Electric announced on January 15, 2007, that the former was divesting Smiths Aerospace to the latter for GBP£2.4 billion (US$ 4.8 billion).^[20] GE Aviation closed the transaction on May 4, 2007.^[4] Smiths Aerospace, which was an important supplier, became an operating subsidiary of GE Aviation known as GE Aviation Systems. This acquisition will reportedly give the combined unit the clout to resist pricing pressures from its two largest customers, Boeing Commercial Airplanes and EADS/Airbus.^[20] Analysts further assert that it enables General Electric to acquire assets similar to those it desired in its failed bid for Honeywell in 2000.^[20]

Along with the purchase of Smiths Aerospace, the purchase included opening the first University Development Center at Michigan Technological University in Houghton, Michigan, in the effort to work with engineering students to provide training in engineering and software development. The program has performed well and GE Aviation has announced further UDC openings at Kansas State University. In July 2008, governments in the Persian Gulf reached agreements with GE to expand engine maintenance operations there. The Wall Street Journal reported that Mubadala Development Company, which owns Abu Dhabi Aircraft Technologies, an overhaul, and maintenance company, signed an agreement worth an estimated $8 billion with GE; Abu Dhabi Aircraft Technologies will maintain and overhaul GE engines used in commercial aircraft purchased by airlines based in the Persian Gulf.^[21]

On December 23, 2012, GE announced that it has agreed to purchase the aeronautical division of Avio S.p.A., an Italy-based manufacturer of aviation propulsion components and systems for civil and military aircraft, for $4.3 billion U.S. (EUR3.3 billion).^[22]

GE Aviation follows through to develop a supersonic engine concept for Aerion with a configuration accommodating reasonably well requirements for supersonic speed, subsonic speed and noise levels.^[23]

On July 28, 2022, GE announced that GE Aviation will become GE Aerospace (and a successor to the GE company) once the spinoffs of its subsidiaries are completed. GE Aerospace will own GE's trademark, and will license the brand to the other companies.^[24]

Additive manufacturing

Recently, they have started incorporating 3D printing technologies in their engines and have incorporated the manufacturing process in the newly designed GE9X, the largest jet engine in the world.^[25]

GE acquired Arcam EBM for electron beam melting, Concept Laser for laser melting, and material provider AP&C. Metal casting improves through competition with metal additive manufacturing, for which GE Additive believes it will soon compete with metal forging which will then be enhanced in response. Additive manufacturing is focused on new builds but can be used for part replacement: when complexity rise, costs can stays level - for example, replacing a turbine consisting of 300 components with one piece. The electron beam melting has good speed for economy, precision to reduce processing work, and size capability for larger parts; the hot process reduces stresses in the part and penetrates deeper than laser for thicker parts with coarser, cheaper metal powders. Additive techniques can be used across the engine and even in the over 1,500 °F (820 °C) hot section. They are used in the CT7 combustor liner, for GE9X low pressure turbine blades - the first rotating parts - and for 16 parts in the ATP, including an 80 parts heat exchanger consolidated into one.^[26]

Turbojets

Turbofans

Turboprops

Propfans

Turboshafts

Vehicle propulsion

Industrial aero-derivative and marine propulsion

• La-Chun Lindsay
• Gerhard Neumann
• University Development Center

Notes

Bibliography

• Leyes II, Richard A.; Fleming, William A. (1999), "10", The History of North American Small Gas Turbine Aircraft Engines, Washington, DC: Smithsonian Institution, p. 725, ISBN 978-1-56347-332-6, retrieved 2011-07-04
• Neumann, Gerhard (2004), Herman the German: Just Lucky I Guess, Bloomington, IN, USA: Authorhouse, ISBN 978-1-4184-7925-1

• Official website  
• GE Aviation YouTube channel
• Aviage Systems Web site
• Guy Norris. "GE at 100: Taking Power to the Skies Aviation Week & Space Technology". Aviation Week & Space Technology.
• Guy Norris (Jul 11, 2019). "GE Aviation At 100: Milestone Engines And People". Aviation Week & Space Technology.