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==Design==
==Design==


The XA100 is a three-stream adaptive cycle engine that can adjust the bypass ratio and fan pressure to increase fuel efficiency or thrust, depending on the scenario. It does this by employing an adaptive fan that can direct air into a third bypass stream in order to increase fuel economy and act as a heat sink for cooling; in particular, this would enable greater use of the high speed, low altitude part of the F-35 envelope. The increased cooling and power generation also enables the potential employment of [[Directed-energy weapon|directed energy weapons]] in the future.<ref>{{cite web |last=Mathews |first=Jim |url=https://www.airforcemag.com/article/engines-of-innovation/ |title=Engines of Innovation |work=Air Force Magazine |date=26 June 2017 |access-date=11 January 2020}}</ref><ref>{{cite web |last1=Norris |first1=Guy |last2=Anselmo |first2=Joe |url=https://aviationweek.com/shownews/farnborough-airshow/f-35-engine-upgrade-would-enable-directed-energy-weapons |title=F-35 Engine Upgrade Would Enable Directed Energy Weapons |work=Aviation Week |date=21 July 2018 |access-date=11 January 2020}}</ref> When additional thrust is needed, the air from the third stream can be directed to the core and fan streams. In addition to three-stream adaptive cycle configuration, the engine also uses new heat-resistant materials such as [[ceramic matrix composite]]s (CMC) to enable higher turbine temperatures and improved performance. According to GE, the engine can offer up to 35% increased range and 25% reduction in fuel burn over current low-bypass turbofans.
The XA100 is a three-stream adaptive cycle engine that can adjust the bypass ratio and fan pressure to increase fuel efficiency or thrust, depending on the scenario. It does this by employing an adaptive fan that can direct air into a third bypass stream in order to increase fuel economy and act as a heat sink for cooling; in particular, this would enable greater use of the high speed, low altitude part of the F-35 envelope. The increased cooling and power generation also enables the potential employment of [[Directed-energy weapon|directed energy weapons]] in the future.<ref>{{cite web |last=Mathews |first=Jim |url=https://www.airforcemag.com/article/engines-of-innovation/ |title=Engines of Innovation |work=Air Force Magazine |date=26 June 2017 |access-date=11 January 2020}}</ref><ref>{{cite web |last1=Norris |first1=Guy |last2=Anselmo |first2=Joe |url=https://aviationweek.com/shownews/farnborough-airshow/f-35-engine-upgrade-would-enable-directed-energy-weapons |title=F-35 Engine Upgrade Would Enable Directed Energy Weapons |work=Aviation Week |date=21 July 2018 |access-date=11 January 2020}}</ref> When additional thrust is needed, the air from the third stream can be directed to the core and fan streams. In addition to three-stream adaptive cycle configuration, the engine also uses new heat-resistant materials such as [[ceramic matrix composite]]s (CMC) to enable higher turbine temperatures and improved performance. According to GE, the engine can offer up to 35% increased range and 25% reduction in fuel burn over current low-bypass turbofans.<ref name="NGAD_engine_makers">{{cite web |last1=Norris |first1=Guy |last2=Trimble |first2=Steve |url=https://aviationweek.com/defense/aircraft-propulsion/pentagon-ngad-uncertainty-pressures-adaptive-engine-makers-adapt |title=Pentagon NGAD Uncertainty Pressures Adaptive Engine-Makers To "Adapt" |date=9 September 2024 |work=Aviation Week & Space Technology}}</ref>


==Applications==
==Applications==
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|ref=Flight Global,<ref name="fg20180709"/>
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|type=Three-stream adaptive cycle engine
|type=Three-stream adaptive cycle engine
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|diameter=
|weight=
|weight=
|compressor=3-stage adaptive fan
|compressor=3-stage adaptive fan, 7-stage compressor
*'''[[Bypass ratio]]:''' Variable
|combustion=Annular
|combustion=Annular
|turbine=2-stage high pressure, 2-stage low-pressure
|turbine=
|fueltype=
|fueltype=
|oilsystem=
|oilsystem=

Revision as of 23:48, 11 September 2024

XA100
XA100 on test stand
Type Adaptive cycle engine
National origin United States
Manufacturer General Electric
First run December 2020
Major applications Lockheed Martin F-35 Lightning II (planned)

The General Electric XA100 is an American adaptive cycle engine demonstrator being developed by General Electric (GE) for the Lockheed Martin F-35 Lightning II and form the technological foundation for the company's XA102 propulsion system for the United States Air Force's sixth generation fighter program, the Next Generation Air Dominance (NGAD).

The three-stream adaptive cycle design can direct air to the bypass third stream for increased fuel efficiency and cooling or to the core and fan streams for additional thrust and performance. The 45,000 lbf (200 kN) thrust class engine is expected to be significantly more powerful and efficient than existing low-bypass turbofans.

Development

The U.S. Air Force and U.S. Navy began pursuing adaptive cycle engine in 2007 with the Adaptive Versatile Engine Technology (ADVENT) program, a part of the larger Versatile Affordable Advanced Turbine Engines (VAATE) program.[1] This technology research program was then followed by the Adaptive Engine Technology Demonstrator (AETD) program in 2012, which continued to mature the technology, with tests performed using demonstrator engines. GE's ground demonstrator consists of a three-stage adaptive fan and a high pressure compressor derived from CFM LEAP’s ten-stage compressor; the tests in 2015 yielded the highest combined compressor and turbine temperatures in the history of jet propulsion.[2] The follow-on Adaptive Engine Transition Program (AETP) was launched in 2016 to develop and test adaptive engines for sixth generation fighter propulsion as well as potential re-engining of the F-35 from the existing F135 turbofan engine. The demonstrators were assigned the designation XA100 for General Electric's design and XA101 for Pratt & Whitney's. The AETP goal is to demonstrate 25% improved fuel efficiency, 10% additional thrust, and significantly better thermal management.[3] Further contract awards and modifications from Air Force Life Cycle Management Center (AFLCMC) in 2018 increased the focus on re-engining of the F-35, and GE's design became "F-35 design-centric"; there has also been investigations on applying the technology in upgrades for F-15, F-16, and F-22 propulsion systems.[4] GE's detailed design was completed in February 2019, and initial testing at GE's high-altitude test facility in Evendale, Ohio was concluded in May 2021.[5][6][7] GE expects that the A100 can enter service with the F-35A and C in 2027 at the earliest.[8]

Design

The XA100 is a three-stream adaptive cycle engine that can adjust the bypass ratio and fan pressure to increase fuel efficiency or thrust, depending on the scenario. It does this by employing an adaptive fan that can direct air into a third bypass stream in order to increase fuel economy and act as a heat sink for cooling; in particular, this would enable greater use of the high speed, low altitude part of the F-35 envelope. The increased cooling and power generation also enables the potential employment of directed energy weapons in the future.[9][10] When additional thrust is needed, the air from the third stream can be directed to the core and fan streams. In addition to three-stream adaptive cycle configuration, the engine also uses new heat-resistant materials such as ceramic matrix composites (CMC) to enable higher turbine temperatures and improved performance. According to GE, the engine can offer up to 35% increased range and 25% reduction in fuel burn over current low-bypass turbofans.[11]

Applications

Specifications (XA100-GE-100)

Data from Flight Global,[4] General Electric[11]

General characteristics

  • Type: Three-stream adaptive cycle engine
  • Length:
  • Diameter:
  • Dry weight:

Components

  • Compressor: 3-stage adaptive fan, 7-stage compressor
  • Bypass ratio: Variable
  • Combustors: Annular
  • Turbine: 2-stage high pressure, 2-stage low-pressure

Performance

See also

Related development

Comparable engines

Related lists

References

  1. ^ Thomson, Daniel E. (14 April 2010). Versatile Affordable Advanced Turbine Engines Provide Game Changing Capability with Superior Fuel Efficiency (PDF). 11th Annual Science & Engineering Technology Conference/DoD Tech Expo. Charleston, South Carolina.
  2. ^ Clark, Colin (18 June 2015). "GE Jet Sets Record; Will F-35 Get New AETD Engine?". Breaking Defense. Retrieved 11 January 2020.
  3. ^ Mehta, Aaron (1 July 2016). "US Air Force Funds Next Advanced Engine Stage". DefenseNews. Retrieved 11 January 2020.
  4. ^ a b Trimble, Steven (9 July 2018). "USAF starts work on defining adaptive engine for future fighter". Flight Global. Retrieved 11 January 2020.
  5. ^ Zazulia, Nick (1 March 2019). "Detailed Design Complete for GE's Revolutionary Adaptive Fighter Engine". Avionics International. Retrieved 11 January 2020.
  6. ^ Norris, Guy (29 January 2015). "GE Details Sixth-Generation Adaptive Fighter Engine Plan". Aviation Week. Retrieved 11 January 2020.
  7. ^ Norris, Guy (13 May 2021). "Tests Of GE XA100 Adaptive Combat Engine Exceed Performance Targets". Aviation Week.
  8. ^ Tirpak, John (5 November 2021). "Next-Generation Power for Air Force Fighters". Air Force Magazine.
  9. ^ Mathews, Jim (26 June 2017). "Engines of Innovation". Air Force Magazine. Retrieved 11 January 2020.
  10. ^ Norris, Guy; Anselmo, Joe (21 July 2018). "F-35 Engine Upgrade Would Enable Directed Energy Weapons". Aviation Week. Retrieved 11 January 2020.
  11. ^ a b Norris, Guy; Trimble, Steve (9 September 2024). "Pentagon NGAD Uncertainty Pressures Adaptive Engine-Makers To "Adapt"". Aviation Week & Space Technology.