RL10

RL-10

RL10 Rocket Engine Specifications (original)
Country of origin	United States
Manufacturer	Rocketdyne (North American Aviation)
Application	Upper stage booster
Successor	RL-10A-1
Liquid-fuel engine
Propellant	LOX / LH2
Cycle	Expander cycle |- |Flow rate|| 35 lb/s (16 kg/s)
Configuration
Nozzle ratio	40:1
Performance
Thrust (Vac.)	15,000 to 24,750 pounds-force (67,000–110,100 N)
Chamber pressure	24.00 bar
Isp (Vac.)	433 s
Burn time	470 s
Dimensions
Length	68 in (1.73 m)
Diameter	39 in (0.99 m)
Dry weight	298 lb (135 kg)
Used in
Saturn I / S-IV 2nd stage (×6), Centaur upper stage (×2)

The RL10 was USA's first liquid hydrogen fueled rocket engine, developed by Rocketdyne. Six RL10 engines were used in the S-IV second stage of the Saturn I rocket. One or two RL10 engines are used in the Centaur upper stages of Atlas and Titan rockets. One RL10 is used in the upper stage of Delta IV rockets. An updated version is used in several current launch vehicles.

History

The RL10 was first tested on the ground in 1959, at the Santa Susana Field Laboratory (SSFL) of North American Aviation. It was first flown in 1962 in an unsuccessful suborbital test;^[1] the first successful flight took place on November 27, 1963.^[2][3] 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.^[4]

Improvements

The RL10 has been upgraded over the years. One current model, the RL10B-2, powers the Delta IV second stage, as well as the Delta III second stage. It has been significantly modified from the original RL10 to improve performance. Some of the enhancements include an extendable nozzle and electro-mechanical gimbaling for reduced weight and increased reliability. Current specific impulse is 464 s (equivalent to an exhaust velocity of 4.55 km/s).

Specifications

Original RL10

• Thrust (altitude): 15,000 lbf (66.7 kN)^[5]
• Burn Time: 470 s^[5]
• Design: Expander cycle^{[citation needed]}
• Specific impulse: 433 s (4.25 kN·s/kg)^{[citation needed]}
• 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
• Propellants: LOX & LH2
• Propellant flow: 35 lb/s (16 kg/s)
• Contractor: Pratt & Whitney
• Vehicle application: Saturn I / S-IV 2nd stage - 6-engines
• Vehicle application: Centaur upper stage - 2-engines

Current design

Second stage of a Delta IV Medium rocket featuring an RL10B-2 engine.

RL10B-2 Specifications

• Thrust (altitude): 24,750 lbf (110.1 kN)^[6]
• Design: Expander cycle^[7]
• Specific impulse: 464 s (4.55 kN·s/kg)^[6]
• Engine weight - dry: 610 lb (277 kg)^[6]
• Height: 163 in (4.14 m)^[6]
• Diameter: 87 in (2.21 m)^[6]
• Expansion ratio: 250 to 1
• Mixture ratio: 5.85 to 1 ^[6]
• Propellants: Liquid oxygen & liquid hydrogen^[6]
• Propellant flow: Oxidizer 41.42 lb/s (20.6 kg/s), fuel 7.72 lb/s (3.5 kg/s)^[6]
• Contractor: Pratt & Whitney
• Vehicle application: Delta III, Delta IV second stage (1 engine)

A flaw in the brazing of an RL10B-2 combustion chamber was identified as the cause of failure for the May 4, 1999, Delta III launch carrying the Orion-3 communications satellite.^[8]

RL10A-4-2

The other current model, the RL10A-4-2, is the engine used on Centaur upper stage for Atlas V.^[6]

Other rockets using RL10

Four modified RL10A-5 engines, all of them with the ability to be throttled, were used in the McDonnell Douglas DC-X.^{[citation needed]}

The DIRECT version 3.0 proposal to replace Ares I and Ares V with a family of rockets sharing a common core stage, recommends the RL10 for the second stage of their proposed J-246 and J-247 launch vehicles.^[9] Up to seven (7) RL10 engines would be used in the proposed Jupiter Upper Stage, serving an equivalent role to the Ares V Earth Departure Stage.

Future use of the RL10

Several potential uses of enhanced versions of the RL10 engine have been proposed:

Manned lunar missions

In 2005 NASA announced the decision to use an Apollo-like spacecraft configuration for the proposed Orion spacecraft. At that time NASA decided that the descent stage of the new Lunar Surface Access Module (LSAM) would be powered by liquid hydrogen and liquid oxygen. The original plan called for the ascent stage to use liquid methane and liquid oxygen, but that has changed^[when?] and the ascent stage will now also use LH2/LOX.^{[citation needed]}

Because of the choice of propellents, along with the need to land the spacecraft in the polar regions of the Moon from an equatorial orbit, NASA decided to use the RL10 as the main powerplant for the descent stage engine.^{[citation needed]} Current specifications call for four RL10 engines to be used on the descent stage and a single RL10 for the ascent stage. Currently, the RL10B-2 engines used on the Delta III and Delta IV can thrust at 20% of maximum thrust. Because of the need for the LSAM to hover above the lunar surface, along with providing a smooth landing, the new RL10 engines must be able to thrust as low as 10%. The use of the RL10 will allow NASA to keep costs on the lunar program down by using existing hardware, albeit modified to enhance performance or allow for manned spaceflight.^{[citation needed]}

Common Extensible Cryogenic Engine

The CECE at full throttle.

The Common Extensible Cryogenic Engine (CECE) is a testbed to develop RL10 engines that throttle well. NASA has contracted with Pratt & Whitney Rocketdyne to develop the CECE demonstrator engine.^[10] In 2007 its operability (with some "chugging") was demonstrated at 11-to-1 throttle ratios.^[11] In 2009 NASA reported successfully throttling from 104 percent thrust to eight percent thrust, a record for an engine of this type. Chugging was eliminated by injector and propellant feed system modifications that control the pressure, temperature and flow of propellants.^[12]

Advanced Common Evolved Stage

As of 2009^[update], an enhanced version of the RL10 rocket engine was proposed to power the upper-stage versions of the Advanced Common Evolved Stage (ACES), a long-duration, low-boiloff extension of existing ULA Centaur and Delta Cryogenic Second Stage (DCSS) technology.^[13] Long-duration ACES technology is explicitly designed to support geosynchronous, cislunar, and interplanetary missions as well as provide 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. Additional missions could include the provision of the high-energy technical capacity for the cleanup of space debris.^[14]

See also

• Spacecraft propulsion
• RD-0146
• XCOR/ULA aluminum alloy nozzle engine, under development in 2011 ff.
• Rocketdyne
• Pratt & Whitney Rocketdyne

References

Notes

1. "Centaur". Gunter's Space Pages. http://space.skyrocket.de/doc_stage/centaur.htm. 
2. Sutton, George (2005). History of liquid propellant rocket engines. American Institute of Aeronautics and Astronautics. ISBN 1563476495. 
3. "Renowned Rocket Engine Celebrates 40 Years of Flight". Pratt & Whitney. November 24, 2003. http://www.pratt-whitney.com/vgn-ext-templating/v/index.jsp?vgnextoid=cabbe002c2f3c010VgnVCM1000000881000aRCRD&vgnextchannel=7dfc34890cb06110VgnVCM1000004601000aRCRD&vgnextfmt=default. 
4. "Atlas Centaur 2". NASA NSSDC. http://nssdc.gsfc.nasa.gov/nmc/spacecraftDisplay.do?id=1963-047A. 
5. ^ 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.: National Aeronautics and Space Administration, NASA History Office, http://history.nasa.gov/SP-4206/ch5.htm, retrieved 2011-12-02 
6. ^ "RL10B-2". Pratt & Whitney Rocketdyne. 2009. http://www.pw.utc.com/products/pwr/assets/pwr_rl10b-2.pdf. Retrieved January 29, 2012. 
7. Sutton, A M; Peery, S D; Minick, A B (January 1998). "50K expander cycle engine demonstration". AIP Conference Proceedings 420: pp. 1062-1065. doi:10.1063/1.54719. http://www.dtic.mil/cgi-bin/GetTRDoc?AD=ADA397948. 
8. "Delta 269 (Delta III) Investigation Report". Boeing. August 16, 2000. MDC 99H0047A. Archived from the original on June 16, 2001. http://web.archive.org/web/20010616012841/http://www.boeing.com/defense-space/space/delta/delta3/d3_report.pdf. 
9. "Jupiter Launch Vehicle – Technical Performance Summaries" (html). Archived from the original on 2009-06-08. http://www.launchcomplexmodels.com/Direct/documents/Baseball_Cards/. Retrieved 2009-07-18. 
10. "CECE". United Technologies Corporation. http://www.pw.utc.com/vgn-ext-templating/v/index.jsp?vgnextrefresh=1&vgnextoid=91380e78738ee010VgnVCM100000c45a529fRCRD. 
11. "Throttling Back to the Moon". NASA. 2007-07-16. http://science.nasa.gov/headlines/y2007/16jul_cece.htm. 
12. "NASA Tests Engine Technology for Landing Astronauts on the Moon". NASA. Jan. 14, 2009. http://www.nasa.gov/home/hqnews/2009/jan/HQ_09-005_Cryo_engine_test.html. 
13. Kutter, Bernard F.; Frank Zegler, Jon Barr, Tim Bulk, Brian Pitchford (2009). "Robust Lunar Exploration Using an Efficient Lunar Lander Derived from Existing Upper Stages". AIAA. https://info.aiaa.org/tac/SMG/STTC/White%20Papers/DualThrustAxisLander(DTAL)2009.pdf. 
14. Zegler, Frank; Bernard Kutter (2010-09-02). "Evolving to a Depot-Based Space Transportation Architecture". AIAA SPACE 2010 Conference & Exposition. AIAA. http://www.ulalaunch.com/site/docs/publications/DepotBasedTransportationArchitecture2010.pdf. Retrieved 2011-01-25. "ACES design conceptualization has been underway at ULA for many years. It leverages design features of both the Centaur and Delta Cryogenic Second Stage (DCSS) upper stages and intends to supplement and perhaps replace these stages in the future. ..." 

Bibliography

• Connors, Jack (2010). The Engines of Pratt & Whitney: A Technical History. Reston. Virginia: American Institute of Aeronautics and Astronautics. ISBN 978-1-60086-711-8. 

External links

• RL10B-2 at Astronautix
• Spaceflight Now article
• Spaceflight Now article