LE-7

LE-7

LE-7, Nagoya City Science Museum, 2006
Country of origin	Japan
Designer	JAXA
Manufacturer	Mitsubishi Heavy Industries
Application	Booster
Status	Succeeded by LE-7A upgrade
Liquid-fuel engine
Propellant	LOX/LH2
Mixture ratio	5.9:1
Cycle	Staged combustion
Configuration
Chamber	1
Nozzle ratio	52:1
Performance
Thrust, vacuum	1,078 kN (242,000 lbf)
Thrust, sea-level	843.5 kN (189,600 lbf)
Thrust-to-weight ratio	64.13
Chamberpressure	12.7 MPa (1,840 psi)
Specific impulse,vacuum	446 seconds (4.37 km/s)
Specific impulse,sea-level	349 seconds (3.42 km/s)
Dimensions
Length	3.4 m
Dry mass	1,714 kg (3,779 lb)
Used in
H-IIfirst stage

TheLE-7and its succeeding upgrade model the LE-7A arestaged combustion cycleLH₂/LOXliquid rocket enginesproduced inJapanfor theH-IIseries of launch vehicles. Design and production work was all done domestically in Japan, the first major (main/first-stage) liquid rocket engine with that claim, in a collaborative effort from the National Space Development Agency (NASDA), Aerospace Engineering Laboratory (NAL),Mitsubishi Heavy Industries,andIshikawajima-Harima.NASDA and NAL have since been integrated intoJAXA.However, a large part of the work was contracted to Mitsubishi, with Ishikawajima-Harima providingturbomachinery,and the engine is often referred to as theMitsubishi LE-7(A).

The original LE-7 was anexpendable,high efficiency, medium-sized motor with sufficient thrust for use on the H-II.

The fuelturbopumphad an issue using the originally designed inducer (a propeller-likeaxial pumpused to raise the inlet pressure of thepropellantahead of the mainturbopumpsto preventcavitation) where the inducer would itself begin to cavitate and cause an imbalance resulting in excessivevibration.A comprehensive post-flight analysis of the unsuccessful 8th H-II launch, including a deep ocean retrieval of the wreckage, determined thatfatiguedue to this vibration was the cause of premature engine failure.

The LE-7A is an upgraded model from the LE-7 rocket engine. Basic design is unchanged from the original model. The 7A had additional engineering effort placed on cost cutting, reliability, and performance developments. The renovation was undertaken to mate it with the likewise improvedH-IIAlaunch vehicle, with the common goal being a more reliable, more powerful and flexible, and more cost effective launch system.

Specific emphasis was placed on reducing or the amount of requiredweldingby allowing for moremachinedorcastcomponents, and to simplify as many of the remaining welds as possible. This resulted in a substantial rework of the pipe routing (which makes the outward appearance of the two models considerably different). To combat the fuel inducer complications described above, the fuel inducer was redesigned for the 7A. The oxidizer inducer was also redesigned, but this was primarily due to poor performance at low inlet pressures as opposed to reliability concerns. The fuel turbopump itself was also the subject of various durability enhancements. Additionally the combustion chamber/injector assembly underwent a number of small changes, like decreasing the number of injector elements, to reduce machining complexity (and thus cost) and improve reliability. While these changes overall resulted in a drop in maximum specific impulse to 440 seconds (4.3 km/s) (basically making the engine less fuel efficient), the trade off for lower cost and enhanced reliability was considered acceptable.

For the new engine model, anozzleextension was designed that could be added to the base of the new standard “short” nozzle when extra performance was required. But when the engine was fitted with the nozzle extension, the 7A encountered a new problem with unprecedented side-loads and irregular heating on the nozzle strong enough to damage thegimbalactuatorsandregenerative coolingtubes during startup. Meticulouscomputational fluid dynamics (CFD)work was able to sufficiently replicate and trace the dangerous transient loading and a new one-piece “long” nozzle with full regenerative cooling (as opposed to the original short nozzle with a separate film-cooled extension) was designed to mitigate the problem. Before this new nozzle was ready, some H-IIA's were launched using only the short nozzle. The 7A no longer uses a separate nozzle extension in any configuration.^[1]

The newH-IIBlaunch vehicles uses two LE-7A engines in its first stage.^[2]

• Operational cycle: staged combustion
• Fuel: hydrogen
• Oxidizer: liquid oxygen
• Mixture ratio (oxidizer to fuel): 5.90
• Short nozzle:
  • Rated thrust (sea level): 843 kN (190,000 lbf)
  • Rated thrust (vacuum): 1,074 kN (241,000 lbf)
  • Specific impulse (sea level):
  • Specific impulse (vacuum): 429 seconds (4.21 km/s)
• Long nozzle:
  • Rated thrust (sea level): 870 kN (200,000 lbf)
  • Rated thrust (vacuum): 1,098 kN (247,000 lbf)
  • Specific impulse (sea level): 338 seconds (3.31 km/s)
  • Specific impulse (vacuum): 440 seconds (4.3 km/s)
• Dry mass: 1,800 kg (4,000 lb)
• Length:
  • short nozzle: 3.2 m
  • long nozzle: 3.7 m
• Throttle capability: 72–100%
• Thrust-to-weight: 65.9
• Nozzle area ratio: 51.9:1
• Combustion chamber pressure: 12.0 MPa (1,740 psi)
• Liquid hydrogen turbopump: 41,900 rpm
• Liquid oxygen turbopump: 18,300 rpm

• LE-5
• LE-9
• H-II,H-IIA,&H-IIB
• Comparison of orbital rocket engines
• Liquid-fuel rocket
• Staged combustion cycle
• JAXA

Wikimedia Commons has media related toLE-7.

• Encyclopedia Astronautica info page on the LE-7
• Encyclopedia Astronautica info page on the LE-7A
• Japanese Wikipedia LE-7 page (in Japanese)
• Japanese Wikipedia LE-7A page (in Japanese)
• H-IIA Rocket Engine Development
• Overview of the H-IIA Launch VehicleIncludes H-IIA-F6 failure analysis