General Electric YF120

YF120
Type	Variable Cycle Turbofan
National origin	United States
Manufacturer	General Electric
First run	1980s
Major applications	Lockheed YF-22 Northrop YF-23
Developed into	General Electric/Rolls-Royce F136

The General Electric YF120 was a variable cycle turbofan engine designed by GE Aircraft Engines in the late 1980s/early 1990s for the United States Air Force's Advanced Tactical Fighter (ATF) project (which resulted in the F-22 Raptor). GE lost the engine competition for this aircraft to Pratt & Whitney F119.

Development and design

General Electric began developing the YF120 for the ATF competition in the early 1980s. Unlike competitor Pratt & Whitney, GE elected against developing a conventional low bypass turbofan and instead chose to design a variable cycle engine. This decision was made as a result of the challenging ATF requirement of supercruise. This meant the engine had to produce a large amount of dry thrust (without afterburner) and therefore have high off-design efficiency ("design" being standard cruise conditions).^[1]

The core technology used in the YF120 was developed during two industry-government programs, the Advanced Technology Engine Gas Generator (ATEGG) and Joint Technology Demonstration Engine (JTDE) programs.^[2]

On 3 November 1990, a YF-22 powered by two General Electric YF120s set a supercruise record of Mach 1.58.^[3]

Variable cycle

The YF120's variable cycle system worked by varying the bypass ratio of the engine for different flight regimes, allowing the engine to act like either a low bypass turbofan or nearly a turbojet.^[1] As a low bypass turbofan (like competitor F119), the engine performed similarly to comparable engines. When needed, however, the engine could direct more airflow through the hot core of the engine (like a turbojet), increasing the specific thrust of the engine. This made the engine more efficient at high altitude, high thrust levels than a traditional low bypass turbofan.^[4]

An expected disadvantage of this variable cycle system would be increased complexity and weight. GE claims to have combated this by using simple pressure driven valves rather than complex mechanically actuated valves to divert airflow. GE stated that this system resulted in the variable cycle system adding only 10 lb to the engine.^[1] Additionally, a production F120 engine was expected to have 40% fewer parts than the F110 engine.^[2]

Thrust vectoring

The YF120 engine featured a two-dimensional thrust vectoring nozzle. The nozzle allowed for vectoring in the pitch direction. This capability gave the aircraft it was installed in a serious advantage in pitch agility by greatly increasing the amount of nose pitching moment available to the aircraft. The pitching moment is traditionally generated by the horizontal stabilizer (and/or canard, if applicable), but with a thrust vectoring nozzle that moment can be augmented by the thrust of the engine.

While the YF120 engine never went into production, it was installed in the YF-22 used for the high angle of attack demonstration program as part of the ATF competition. During this demonstration, the YF120 powered aircraft flew, trimmed, at 60 degrees angle of attack at 82 knots. At this attitude the aircraft was able to demonstrate controlibility. Later analysis revealed that the aircraft could have maintained controlled, trimmed flight up to 70 degrees angle of attack.^[5]

Advanced development

The YF120 was also proposed as the basis for a more exotic engine, the Turbine-Based Combined Cycle (TBCC) engine that was to be used in demonstrator aircraft like the X-43B and future hypersonic aircraft. Specifically, the YF120 was to be the basis for the Revolutionary Turbine Accelerator (RTA-1). The variable cycle technology used in the YF120 would be extended to not only turn the engine into a turbojet but also into a ramjet. In that mode all airflow would bypass the core and be diverted into the afterburner-like "hyperburner" where it would be combusted like a ramjet. This proposed engine was to accelerate from 0 to Mach 4.1 (at 56,000 ft) in eight minutes.^[6]^[7]

Applications

Specifications (YF120)

Data from Aronstein^[8]

General characteristics

Type: Twin-Spool, Augmented Turbofan
Length: 4,242 mm (167.0 in)
Diameter: 1,067 mm (42.0 in)
Dry weight: 1,860 kg (4,100 lb)

Components

Compressor: Two stage fan, five stage high pressure compressor (estimated^[2])
Bypass ratio: 0.32:1
Combustors: Annular Combustor
Turbine: Single stage HPT, Counter-Rotating Single Stage LPT ^[9]
Nozzle: Two Dimensional Vectoring Convergent/Divergent
Fuel type: JP-4 or JP-8

Performance

Maximum thrust: 35,000 lbf (160 kN) - class
Power-to-weight ratio:

References

1 2 3 Moxon, Julian (1989). ATF rivals ready for engine contest. Flight International. 15-21 Nov 1989, pg. 22-23.
1 2 3 Norris, Guy (1990). Power Struggle. Flight International. 1-7 Aug 1990, pg. 22-23
↑ "YF-22 PAV-1 breaks supercruise speed record". Defense Daily. 19 November 1990. Retrieved 10 August 2015 – via HighBeam Research. (subscription required (help)).
↑ GE F120 Powerplant Uses Fan Bypass Door to Regulate Variable Cycle (1990). Aviation Week and Space Technology. 30 Jul 1990. Vol. 133, No. 5; pg. 21
↑ Barham, Robert (1994). THRUST VECTOR AIDED MANEUVERING OF THE YF-22 ADVANCED TACTICAL FIGHTER PROTOTYPE. AIAA-94-2105-CP.
↑ Norris, Guy (2003). GE unveils ramjet design for shuttle. Flight International. 23 Sept 2003, pg. 26.
↑ Mach 7 engine to be turbine-based (2004). Flight International. 23 Dec 2003 - 5 Jan 2004, pg. 13.
↑ Aronstein pp. 224
↑ Kauser, Fazel (1994). An Overview of Gas Turbine Propulsion Technology. 30th AIAA/ASME/SAE/ASEE Joint Propulsion Conference. 27-29 Jun 1994, Indianapolis, IN. AlAA 94-2828.

GE unveils ramjet design for shuttle Technology News Flight International 23/09/03 .
Aronstein, David C.; Hirschberg, Michael J. (1998). Advanced Tactical Fighter to F-22 Raptor: Origins of the 21st Century Air Dominance Fighter. Arlington, Virginia: American Institute of Aeronautics & Astronomy. ISBN 978-1-56347-282-4.

External links

GE/Allison/Rolls-Royce Team Developing YF120 Fighter Engine for JSF Aircraft Candidates. Press release GE Aviation (Sept 2, 1996).
Northrop YF-23 Enthusiast's site

General Electric aircraft engines

Turbojets	CJ610 CJ805 GE1 GE4/J5P J31 J33 J35 J47 J73 J79 J85 J87 YJ93 J97 YJ101

Turbofans	CF6 CF34 CF700 CFE738† CFM56/F108† CJ805-23 F101 F110 F118 YF120 F136† F404/F412/RM12 F414 GE90 GEnx GP7000† HF120† LEAP† Passport TF34 TF39 RM12

Turboprops/Turboshafts	GE27 GE36 GE38-1B GE93 H80 T31 T58/CT58 T64/CT64 T407 T408 T700/CT7

Aeroderivative gas turbine engines	LM500 LM1500 LM1600 LM2500 LM6000 LMS100 LV100†

† Joint development aeroengines

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 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 T800

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 F135 F136 F137 F138 F400 F401 F402 F404 F405 F408 F412 F414 F415

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