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RL10 - Wikipedia

The RL10 is a liquid-fuel cryogenic rocket engine built in the United States by Aerojet Rocketdyne that burns cryogenic liquid hydrogen and liquid oxygen propellants. Modern versions produce up to 110 kN (24,729 lbf) of thrust per engine in vacuum. Three RL10 versions are in production for the Centaur upper stage of the Atlas V and the DCSS of the Delta IV. Three more versions are in development for the Exploration Upper Stage of the Space Launch System and the Centaur V of the Vulcan rocket.[2]

RL10
An RL10A-4 engine in London's Science Museum
Country of originUnited States
First flight1962 (1962) (RL10A-1)
ManufacturerAerojet Rocketdyne
ApplicationUpper stage engine
Associated LVAtlas · Delta III · Delta IV · Saturn I · SLS · Titan IIIE · Titan IV · Vulcan Centaur
Canceled: DC-X · OmegA · Space Shuttle
StatusIn production
Liquid-fuel engine
PropellantLOX / LH2
Mixture ratio5.88:1
CycleExpander cycle
Configuration
Nozzle ratio84:1 or 280:1
Performance
Thrust, vacuum110.1 kN (24,800 lbf)
Specific impulse, vacuum465.5 s (4.565 km/s)
Dimensions
Length4.15 m (13.6 ft) w/ nozzle extended
Diameter2.15 m (7 ft 1 in)
Dry mass301 kg (664 lb)
Used in
Centaur, DCSS, S-IV
References
References[1]
NotesPerformance values and dimensions are for RL10B-2.

The expander cycle that the engine uses drives the turbopump with waste heat absorbed by the engine combustion chamber, throat, and nozzle. This, combined with the hydrogen fuel, leads to very high specific impulses (Isp) in the range of 373 to 470 s (3.66–4.61 km/s) in a vacuum. Mass ranges from 131 to 317 kg (289–699 lb) depending on the version of the engine.[3][4]

History

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The RL10 was the first liquid hydrogen rocket engine to be built in the United States, with development of the engine by Marshall Space Flight Center and Pratt & Whitney beginning in the 1950s. The RL10 was originally developed as a throttleable engine for the USAF Lunex lunar lander.[5]

The RL10 was first tested on the ground in 1959, at Pratt & Whitney's Florida Research and Development Center in West Palm Beach, Florida.[6][7] The first successful flight took place on November 27, 1963.[8][9] For that launch, two RL10A-3 engines powered the Centaur upper stage of an Atlas launch vehicle. The launch was used to conduct a heavily instrumented performance and structural integrity test of the vehicle.[10]

Multiple versions of this engine have been flown. The S-IV of the Saturn I used a cluster of six RL10A-3S, a version which was modified for installation on the Saturn[11] and the Titan program included Centaur D-1T upper stages powered by two RL10A-3-3 Engines.[11][12]

Four modified RL10A-5 engines were used in the McDonnell Douglas DC-X.[13]

A flaw in the brazing of an RL10B-2 combustion chamber was identified as the cause of failure for the 4 May 1999 Delta III launch carrying the Orion-3 communications satellite.[14]

The DIRECT version 3.0 proposal to replace Ares I and Ares V with a family of rockets sharing a common core stage recommended the RL10 for the second stage of the J-246 and J-247 launch vehicles.[15] Up to seven RL10 engines would have been used in the proposed Jupiter Upper Stage, serving an equivalent role to the Space Launch System Exploration Upper Stage.

Common Extensible Cryogenic Engine

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The CECE at partial throttle

In the early 2000s, NASA contracted with Pratt & Whitney Rocketdyne to develop the Common Extensible Cryogenic Engine (CECE) demonstrator. CECE was intended to lead to RL10 engines capable of deep throttling.[16] In 2007, its operability (with some "chugging") was demonstrated at 11:1 throttle ratios.[17] In 2009, NASA reported successfully throttling from 104 percent thrust to eight percent thrust, a record for an expander cycle engine of this type. Chugging was eliminated by injector and propellant feed system modifications that control the pressure, temperature and flow of propellants.[18] In 2010, the throttling range was expanded further to a 17.6:1 ratio, throttling from 104% to 5.9% power.[19]

Early 2010s possible successor

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In 2012 NASA joined with the US Air Force (USAF) to study next-generation upper stage propulsion, formalizing the agencies' joint interests in a new upper stage engine to replace the Aerojet Rocketdyne RL10.

"We know the list price on an RL10. If you look at cost over time, a very large portion of the unit cost of the EELVs is attributable to the propulsion systems, and the RL10 is a very old engine, and there's a lot of craftwork associated with its manufacture. ... That's what this study will figure out, is it worthwhile to build an RL10 replacement?"

— Dale Thomas, Associated Director Technical, Marshall Space Flight Center[20]

From the study, NASA hoped to find a less expensive RL10-class engine for the upper stage of the Space Launch System (SLS).[20][21]

USAF hoped to replace the Rocketdyne RL10 engines used on the upper stages of the Lockheed Martin Atlas V and the Boeing Delta IV Evolved Expendable Launch Vehicles (EELV) that were the primary methods of putting US government satellites into space.[20] A related requirements study was conducted at the same time under the Affordable Upper Stage Engine Program (AUSEP).[21]

Improvements

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The RL10 has evolved over the years. The RL10B-2 that was used on the DCSS had improved performance, an extendable carbon-carbon nozzle, electro-mechanical gimbaling for reduced weight and increased reliability, and a specific impulse of 465.5 seconds (4.565 km/s).[22][23]

As of 2016, Aerojet Rocketdyne was working toward incorporating additive manufacturing into the RL10 construction process. The company conducted full-scale, hot-fire tests on an engine with a printed main injector in March 2016,[24] and on an engine with a printed thrust chamber assembly in April 2017.[25]

Current applications for the RL10

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  • Atlas V Centaur (rocket stage): The single engine centaur (SEC) version uses the RL10C-1,[2] while the dual engine centaur (DEC) version retains the smaller RL10A-4-2.[26] An Atlas V mission (SBIRS-5) marked the first use of the RL10C-1-1 version. The mission was successful but observed unexpected vibration, and further use of the RL10C-1-1 model is on hold until the problem is better understood.[27] The engine was used again successfully on SBIRS-6.
  • Interim Cryogenic Propulsion Stage : The Interim Cryogenic Propulsion Stage or ICPS is used for the SLS and is similar to the DCSS, except that the engine is an RL10B-2 and it is adapted to fit on top of the 8.4 meter diameter core stage with four RS-25 Space Shuttle Main Engines.
  • Vulcan Centaur's Centaur V stage: On May 11, 2018, United Launch Alliance (ULA) announced that the RL10 upper stage engine had been selected for ULA's next-generation Vulcan Centaur rocket following a competitive procurement process.[28] Centaur V will normally use the RL10C-1-1,[2] but on Vulcan Centaur Heavy the RL10C-X will be used.[29] Vulcan flew its successful maiden flight on January 8, 2024.[30]

Engines in development

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Advanced Cryogenic Evolved Stage

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As of 2009, an enhanced version of the RL10 was proposed to power the Advanced Cryogenic Evolved Stage (ACES), a long-duration, low-boiloff extension of existing ULA Centaur and Delta Cryogenic Second Stage (DCSS) technology for the Vulcan launch vehicle.[34] Long-duration ACES technology is intended to support geosynchronous, cislunar, and interplanetary missions. Another possible application is as in-space propellant depots in LEO or at L2 that could be used as way-stations for other rockets to stop and refuel on the way to beyond-LEO or interplanetary missions. Cleanup of space debris was also proposed.[35]

Table of versions

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Partial specifications

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All versions

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  • Contractor: Pratt & Whitney
  • Propellants: liquid oxygen, liquid hydrogen[23]
  • Design: expander cycle[56]
  • Ignition: electric spark.[57]

RL10A

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RL10A information and overview
  • Thrust (altitude): 15,000 lbf (66.7 kN)[36]
  • Specific impulse: 433 seconds (4.25 km/s)
  • Engine weight, dry: 298 lb (135 kg)
  • Height: 68 in (1.73 m)
  • Diameter: 39 in (0.99 m)
  • Nozzle expansion ratio: 40 to 1
  • Propellant flow: 35 lb/s (16 kg/s)
  • Vehicle application: Saturn I, S-IV 2nd stage, 6 engines
  • Vehicle application: Centaur upper stage, 2 engines

RL10B-2

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Second stage of a Delta IV Medium rocket featuring an RL10B-2 engine
  • Thrust (altitude): 24,750 lbf (110.1 kN)[23]
  • Specific impulse: 465.5 seconds (4.565 km/s)[23]
  • Engine weight, dry: 664 lb (301.2 kg)[23]
  • Height: 163.5 in (4.14 m)[23]
  • Diameter: 84.5 in (2.21 m)[23]
  • Expansion ratio: 280 to 1
  • Mixture ratio: 5.88 to 1 oxygen:hydrogen mass ratio[23]
  • Propellant flow: fuel, 7.72 lb/s (3.5 kg/s); oxidizer 45.42 lb/s (20.6 kg/s)[23]
  • Vehicle application: Delta III, Delta IV second stage (1 engine)
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Engines on display

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See also

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References

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  1. ^ a b Wade, Mark (November 17, 2011). "RL-10B-2". Encyclopedia Astronautica. Archived from the original on February 4, 2012. Retrieved February 27, 2012.
  2. ^ a b c d e f "Aerojet Rocketdyne RL10 Propulsion System" (PDF). Aerojet Rocketdyne. Archived from the original (PDF) on January 30, 2022.
  3. ^ "RL-10C". www.astronautix.com. Archived from the original on December 28, 2016. Retrieved April 6, 2020.
  4. ^ "RL-10A-1". www.astronautix.com. Archived from the original on December 28, 2016. Retrieved April 6, 2020.
  5. ^ Wade, Mark. "Encyclopedia Astronautica—Lunex Project page". Encyclopedia Astronautica. Archived from the original on August 31, 2006.
  6. ^ Connors, p 319
  7. ^ "Centaur". Gunter's Space Pages.
  8. ^ a b Sutton, George (2005). History of liquid propellant rocket engines. American Institute of Aeronautics and Astronautics. ISBN 1-56347-649-5.
  9. ^ "Renowned Rocket Engine Celebrates 40 Years of Flight". Pratt & Whitney. November 24, 2003. Archived from the original on June 14, 2011.
  10. ^ "Atlas Centaur 2". National Space Science Data Center. NASA.
  11. ^ a b c d e f g h i j Brügge, Norbert. "Evolution of Pratt & Whitney's cryogenic rocket engine RL-10". Retrieved September 16, 2022.
  12. ^ "Titan 3E/Centaur D-1T Systems Summary REPORT NO. CASD·LVP73-007" (PDF). Convair & Martin Marietta Aerospace. September 1, 1973. pp. 2–4. Retrieved September 16, 2022.
  13. ^ Wade, Mark. "DCX". Encyclopedia Astronautica. Archived from the original on December 28, 2012. Retrieved January 4, 2013.
  14. ^ "Delta 269 (Delta III) Investigation Report" (PDF). Boeing. August 16, 2000. MDC 99H0047A. Archived from the original (PDF) on June 16, 2001.
  15. ^ "Jupiter Launch Vehicle – Technical Performance Summaries". Archived from the original on January 29, 2009. Retrieved July 18, 2009.{{cite web}}: CS1 maint: bot: original URL status unknown (link)
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  17. ^ "Throttling Back to the Moon". NASA. July 16, 2007. Archived from the original on April 2, 2010.
  18. ^ "NASA Tests Engine Technology for Landing Astronauts on the Moon". NASA. January 14, 2009.
  19. ^ Giuliano, Victor (July 25, 2010). "CECE: Expanding the Envelope of Deep Throttling Technology in Liquid Oxygen/Liquid Hydrogen Rocket Engines for NASA Exploration Missions" (PDF). NASA Technical Reports Server.
  20. ^ a b c Roseberg, Zach (April 12, 2012). "NASA, US Air Force to study joint rocket engine". Flight Global. Retrieved June 1, 2012.
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  25. ^ "Aerojet Rocketdyne Achieves 3-D Printing Milestone with Successful Testing of Full-Scale RL10 Copper Thrust Chamber Assembly" (Press release). Aerojet Rocketdyne. April 3, 2017. Retrieved April 11, 2017.
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  27. ^ "ULA delays further use of enhanced upper-stage engine pending studies". June 23, 2021.
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  29. ^ "Vulcan Cutaway Poster" (PDF). United Launch Alliance. Retrieved October 15, 2021.
  30. ^ Belam, Martin (January 8, 2024). "Nasa Peregrine 1 launch: Vulcan Centaur rocket carrying Nasa moon lander lifts off in Florida – live updates". the Guardian. ISSN 0261-3077. Retrieved January 8, 2024.
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  36. ^ a b Bilstein, Roger E. (1996). "Unconventional Cryogenics: RL-10 and J-2". Stages to Saturn; A Technological History of the Apollo/Saturn Launch Vehicles. Washington, D.C.: NASA History Office. Retrieved December 2, 2011.
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Bibliography

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