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Aerospike engine

May 21, 2023

The aerospike engine is a type of rocket engine that maintains its aerodynamic efficiency across a wide range of altitudes.[1] It belongs to the class of altitude compensating nozzle engines.[2] Aerospike engines have been studied for several years and are the baseline engines for many single-stage-to-orbit (SSTO) designs and were also a strong contender for the Space Shuttle main engine. However, no such engine is in commercial production, although some large-scale aerospikes are in testing phases.[3]

XRS-2200 linear aerospike engine for the X-33 program being tested at the Stennis Space Center

The terminology in the literature surrounding this subject is somewhat confusing—the term aerospike was originally used for a truncated plug nozzle with a very rough conical taper and some gas injection, forming an "air spike" to help make up for the absence of the plug tail. However, frequently, a full-length plug nozzle is now called an aerospike.

Principles

The purpose of any engine bell is to direct the exhaust of a rocket engine in one direction, generating thrust in the opposite direction. The exhaust, a high-temperature mix of gases, has an effectively random momentum distribution (i.e., the exhaust pushes in any direction it can). If the exhaust is allowed to escape in this form, only a small part of the flow will be moving in the correct direction and thus contribute to forward thrust. The bell redirects exhaust moving in the wrong direction so that it generates thrust in the correct direction. Ambient air pressure also imparts a small pressure against the exhaust, helping to keep it moving in the "right" direction as it exits the engine. As the vehicle travels upward through the atmosphere, ambient air pressure is reduced. This causes the thrust-generating exhaust to begin to expand outside the edge of the bell. Since this exhaust begins traveling in the "wrong" direction (i.e., outward from the main exhaust plume), the efficiency of the engine is reduced as the rocket travels because this escaping exhaust is no longer contributing to the thrust of the engine. An aerospike rocket engine seeks to eliminate this loss of efficiency.[1]

 
Comparison between the design of a bell-nozzle rocket (left) and an aerospike rocket (right)

Instead of firing the exhaust out of a small hole in the middle of a bell, an aerospike engine avoids this random distribution by firing along the outside edge of a wedge-shaped protrusion, the "spike", which serves the same function as a traditional engine bell. The spike forms one side of a "virtual" bell, with the other side being formed by the outside air.[1]

The idea behind the aerospike design is that at low altitude the ambient pressure compresses the exhaust against the spike. Exhaust recirculation in the base zone of the spike can raise the pressure in that zone to nearly ambient. Since the pressure in front of the vehicle is ambient, this means that the exhaust at the base of the spike nearly balances out with the drag experienced by the vehicle. It gives no overall thrust, but this part of the nozzle also doesn't lose thrust by forming a partial vacuum. The thrust at the base part of the nozzle can be ignored at low altitude.[1]

As the vehicle climbs to higher altitudes, the air pressure holding the exhaust against the spike decreases, as does the drag in front of the vehicle. The recirculation zone at the base of the spike maintains the pressure in that zone to a fraction of 1 bar, higher than the near-vacuum in front of the vehicle, thus giving extra thrust as altitude increases. This effectively behaves like an "altitude compensator" in that the size of the bell automatically compensates as air pressure falls.[1]

The disadvantages of aerospikes seem to be extra weight for the spike. Furthermore, the larger cooled area can reduce performance below theoretical levels by reducing the pressure against the nozzle. Aerospikes work relatively poorly between Mach 1–3, where the airflow around the vehicle has reduced the pressure, thus reducing the thrust.[4]

Variations

Several versions of the design exist, differentiated by their shapes. In the toroidal aerospike the spike is bowl-shaped with the exhaust exiting in a ring around the outer rim. In theory this requires an infinitely long spike for best efficiency, but by blowing a small amount of gas out of the center of a shorter truncated spike (like base bleed in an artillery shell), something similar can be achieved.

In the linear aerospike the spike consists of a tapered wedge-shaped plate, with exhaust exiting on either side at the "thick" end. This design has the advantage of being stackable, allowing several smaller engines to be placed in a row to make one larger engine while augmenting steering performance with the use of individual engine throttle control.

Performance

Rocketdyne conducted a lengthy series of tests in the 1960s on various designs. Later models of these engines were based on their highly reliable J-2 engine machinery and provided the same sort of thrust levels as the conventional engines they were based on; 200,000 lbf (890 kN) in the J-2T-200k, and 250,000 lbf (1.1 MN) in the J-2T-250k (the T refers to the toroidal combustion chamber). Thirty years later their work was revived for use in NASA's X-33 project. In this case the slightly upgraded J-2S engine machinery was used with a linear spike, creating the XRS-2200. After more development and considerable testing, this project was cancelled when the X-33's composite fuel tanks repeatedly failed.

 
CSULB aerospike engine

Three XRS-2200 engines were built during the X-33 program and underwent testing at NASA's Stennis Space Center. The single-engine tests were a success, but the program was halted before the testing for the two-engine setup could be completed. The XRS-2200 produces 204,420 lbf (909,300 N) thrust with an Isp of 339 seconds at sea level, and 266,230 lbf (1,184,300 N) thrust with an Isp of 436.5 seconds in a vacuum.

The RS-2200 Linear Aerospike Engine[5] was derived from the XRS-2200. The RS-2200 was to power the VentureStar single-stage-to-orbit vehicle. In the latest design, seven RS-2200s producing 542,000 pounds-force (2,410 kN) each would boost the VentureStar into low earth orbit. The development on the RS-2200 was formally halted in early 2001 when the X-33 program did not receive Space Launch Initiative funding. Lockheed Martin chose to not continue the VentureStar program without any funding support from NASA. An engine of this type is on outdoor display on the grounds of the NASA Marshall Space Flight Center in Huntsville Alabama.

 
NASA's Toroidal aerospike nozzle

The cancellation of the Lockheed Martin X-33 by the federal government in 2001 decreased funding availability, but aerospike engines remain an area of active research. For example, a milestone was achieved when a joint academic/industry team from California State University, Long Beach (CSULB) and Garvey Spacecraft Corporation successfully conducted a flight test of a liquid-propellant powered aerospike engine in the Mojave Desert on September 20, 2003. CSULB students had developed their Prospector 2 (P-2) rocket using a 1,000 lbf (4.4 kN) LOX/ethanol aerospike engine. This work on aerospike engines continues; Prospector-10, a ten-chamber aerospike engine, was test-fired June 25, 2008.[6]

 
Nozzle performance comparison of bell and aerospike nozzle

Further progress came in March 2004 when two successful tests sponsored by the NASA Dryden Flight Research Center using high-power rockets manufactured by Blacksky Corporation, based in Carlsbad, California. The aerospike nozzles and solid rocket motors were developed and built by the rocket motor division of Cesaroni Technology Incorporated, north of Toronto, Ontario. The two rockets were solid-fuel powered and fitted with non-truncated toroidal aerospike nozzles. Flown at the Pecos County Aerospace Development Center, Fort Stockton, Texas, the rockets achieved apogees of 26,000 ft (7,900 m) and speeds of about Mach 1.5.

Small-scale aerospike engine development using a hybrid rocket propellant configuration has been ongoing by members of the Reaction Research Society.

In 2020 the TU Dresden and Fraunhofer IWS started their CFDμSAT-Project for research on additively manufactured aerospike-engines. A prototype has already been tested in a test cell at TU Dresden's Institute of Aerospace Engineering, achieving a burn time of 30 seconds.[7]

Implementations

Firefly Aerospace

In July 2014 Firefly Space Systems announced its planned Alpha launcher that uses an aerospike engine for its first stage. Intended for the small satellite launch market, it is designed to launch satellites into low-Earth orbit (LEO) at a price of US$8–9 million, much lower than with conventional launchers.[8]

Firefly Alpha 1.0 was designed to carry payloads of up to 400 kilograms (880 lb). It uses carbon composite materials and uses the same basic design for both stages. The plug-cluster aerospike engine puts out 90,000 pounds-force (400 kN) of thrust. The engine has a bell-shaped nozzle that has been cut in half, then stretched to form a ring with the half-nozzle now forming the profile of a plug.[8]

This rocket design was never launched. The design was abandoned after Firefly Space Systems went bankrupt. A new company, Firefly Aerospace, has replaced the aerospike engine with a conventional engine in the Alpha 2.0 design. However, the company has proposed Firefly Gamma, a partially reusable spaceplane with aerospike engines.

ARCA Space

In March 2017 ARCA Space Corporation announced their intention to build a single-stage-to-orbit rocket (SSTO), named Haas 2CA, using a linear aerospike engine. The rocket is designed to send up to 100 kg into low-Earth orbit, at a price of US$1 million per launch.[9] They later announced that their Executor Aerospike engine would produce 50,500 pounds-force (225 kN) of thrust at sea level and 73,800 pounds-force (328 kN) of thrust in a vacuum.[10]

In June 2017, ARCA announced that they would fly their Demonstrator3 rocket to space, also using a linear aerospike engine. This rocket was designed to test several components of their Haas 2CA at lower cost. They announced a flight for August 2017.[9] In September 2017, ARCA announced that, after being delayed, their linear aerospike engine was ready to perform ground tests and flight tests on a Demonstrator3 rocket.[9]

On December 20, 2019, ARCA tested the LAS 25DA aerospike steam rocket engine for the Launch Assist System.[11]

KSF Space and Interstellar Space

Another spike engine concept model, by KSF Space and Interstellar Space in Los Angeles, was designed for orbital vehicle named SATORI. Due to lack of funding, the concept is still undeveloped.[12]

Rocketstar

Rocketstar planned to launch its 3D-printed aerospike rocket to an altitude of 50 miles in February 2019 but canceled the mission three days ahead of liftoff citing safety concerns. They are working on a second launch attempt.[13]

Pangea Aerospace

In November 2021, Spain-based Pangea Aerospace began hot-fire testing of its small-scale demonstration methane-oxygen aerospike engine DemoP1. [14][15]

After successfully testing the demonstrator DemoP1, Pangea plans to up-scale to the 300kN ARCOS engine.[16]

Stoke Space

Headquartered in Kent, Washington, Stoke Space is building and testing a distributed architecture LH2/LOX aerospike system for its reusable second stage.[17]

See also

References

  1. ^ a b c d e "NASA - Linear Aerospike Engine fact sheet (08/00)". www.nasa.gov. Retrieved 21 January 2020.
  2. ^ Defusca, Albert; Craddock, Christopher (1 November 2017). "Affordable Access to Low Earth Orbit". DSIAC Journals. 4 (4). Retrieved 16 June 2019.
  3. ^ "Aerospike Engine Homepage". www.hq.nasa.gov.
  4. ^ . ww17.pwrengineering.com. Archived from the original on 2 April 2010.
  5. ^ . Astronautix.com. Archived from the original on 28 December 2016. Retrieved 4 February 2018.
  6. ^ . Archived from the original on 15 June 2008.
  7. ^ "TU-Dresden Homepage". tu-dresden.de. Retrieved 23 April 2021.
  8. ^ a b "Firefly Space Systems unveils Alpha launch vehicle design with aerospike engine". Gizmag.com. 14 July 2014. Retrieved 14 July 2014.
  9. ^ a b c "ARCA News". ARCA Space. ARCA Space. Retrieved 30 May 2018.
  10. ^ "Haas 2CA Specs". ARCA Space. ARCA Space. Retrieved 30 May 2018.
  11. ^ "Flight of the Aerospike: Episode 34 - LAS 25DA Aerospike Engine". Youtube. ARCA Space. Archived from the original on 11 December 2021. Retrieved 5 August 2020.
  12. ^ "SATORI Space Vehicle Rocket". KSF Space.
  13. ^ "RocketStar ready for second suborbital flight attempt". SpaceNews. 27 September 2021. Retrieved 14 December 2021.
  14. ^ "Pangea Aerospace tests aerospike engine". SpaceNews. 20 November 2021. Retrieved 2 January 2022.
  15. ^ "Research Activities in the Development of DemoP1: A LOX/LNG Aerospike Engine Demonstrator". ResearchGate. March 2021. Retrieved 22 December 2022.
  16. ^ "Aerospike Propulsion". Pangea Aerospace. Retrieved 22 December 2022.
  17. ^ "Stoke Space aims to build rapidly reusable rocket with a completely novel design". Arstechnica. 10 October 2022. Retrieved 13 February 2023.

External links

 
Wikimedia Commons has media related to Aerospike rocket engines.
  • Aerospike Engine
  • — includes the J-2T
  • Dryden Flight Research Center
  • Bui, Trong; Murray, James; Rogers, Charles; Bartel, Scott; Cesaroni, Anthony; Dennett, Mike (2005). "Flight Research of an Aerospike Nozzle Using High Power Solid Rockets". 41st AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit. doi:10.2514/6.2005-3797. ISBN 978-1-62410-063-5.
  • Are Aerospikes Better Than Bell Nozzles?

May 21, 2023
aerospike, engine, aerospike, engine, type, rocket, engine, that, maintains, aerodynamic, efficiency, across, wide, range, altitudes, belongs, class, altitude, compensating, nozzle, engines, have, been, studied, several, years, baseline, engines, many, single,. The aerospike engine is a type of rocket engine that maintains its aerodynamic efficiency across a wide range of altitudes 1 It belongs to the class of altitude compensating nozzle engines 2 Aerospike engines have been studied for several years and are the baseline engines for many single stage to orbit SSTO designs and were also a strong contender for the Space Shuttle main engine However no such engine is in commercial production although some large scale aerospikes are in testing phases 3 XRS 2200 linear aerospike engine for the X 33 program being tested at the Stennis Space Center The terminology in the literature surrounding this subject is somewhat confusing the term aerospike was originally used for a truncated plug nozzle with a very rough conical taper and some gas injection forming an air spike to help make up for the absence of the plug tail However frequently a full length plug nozzle is now called an aerospike Contents 1 Principles 1 1 Variations 2 Performance 3 Implementations 3 1 Firefly Aerospace 3 2 ARCA Space 3 3 KSF Space and Interstellar Space 3 4 Rocketstar 3 5 Pangea Aerospace 3 6 Stoke Space 4 See also 5 References 6 External linksPrinciples EditThe purpose of any engine bell is to direct the exhaust of a rocket engine in one direction generating thrust in the opposite direction The exhaust a high temperature mix of gases has an effectively random momentum distribution i e the exhaust pushes in any direction it can If the exhaust is allowed to escape in this form only a small part of the flow will be moving in the correct direction and thus contribute to forward thrust The bell redirects exhaust moving in the wrong direction so that it generates thrust in the correct direction Ambient air pressure also imparts a small pressure against the exhaust helping to keep it moving in the right direction as it exits the engine As the vehicle travels upward through the atmosphere ambient air pressure is reduced This causes the thrust generating exhaust to begin to expand outside the edge of the bell Since this exhaust begins traveling in the wrong direction i e outward from the main exhaust plume the efficiency of the engine is reduced as the rocket travels because this escaping exhaust is no longer contributing to the thrust of the engine An aerospike rocket engine seeks to eliminate this loss of efficiency 1 Comparison between the design of a bell nozzle rocket left and an aerospike rocket right Instead of firing the exhaust out of a small hole in the middle of a bell an aerospike engine avoids this random distribution by firing along the outside edge of a wedge shaped protrusion the spike which serves the same function as a traditional engine bell The spike forms one side of a virtual bell with the other side being formed by the outside air 1 The idea behind the aerospike design is that at low altitude the ambient pressure compresses the exhaust against the spike Exhaust recirculation in the base zone of the spike can raise the pressure in that zone to nearly ambient Since the pressure in front of the vehicle is ambient this means that the exhaust at the base of the spike nearly balances out with the drag experienced by the vehicle It gives no overall thrust but this part of the nozzle also doesn t lose thrust by forming a partial vacuum The thrust at the base part of the nozzle can be ignored at low altitude 1 As the vehicle climbs to higher altitudes the air pressure holding the exhaust against the spike decreases as does the drag in front of the vehicle The recirculation zone at the base of the spike maintains the pressure in that zone to a fraction of 1 bar higher than the near vacuum in front of the vehicle thus giving extra thrust as altitude increases This effectively behaves like an altitude compensator in that the size of the bell automatically compensates as air pressure falls 1 The disadvantages of aerospikes seem to be extra weight for the spike Furthermore the larger cooled area can reduce performance below theoretical levels by reducing the pressure against the nozzle Aerospikes work relatively poorly between Mach 1 3 where the airflow around the vehicle has reduced the pressure thus reducing the thrust 4 Variations Edit Several versions of the design exist differentiated by their shapes In the toroidal aerospike the spike is bowl shaped with the exhaust exiting in a ring around the outer rim In theory this requires an infinitely long spike for best efficiency but by blowing a small amount of gas out of the center of a shorter truncated spike like base bleed in an artillery shell something similar can be achieved In the linear aerospike the spike consists of a tapered wedge shaped plate with exhaust exiting on either side at the thick end This design has the advantage of being stackable allowing several smaller engines to be placed in a row to make one larger engine while augmenting steering performance with the use of individual engine throttle control Performance EditRocketdyne conducted a lengthy series of tests in the 1960s on various designs Later models of these engines were based on their highly reliable J 2 engine machinery and provided the same sort of thrust levels as the conventional engines they were based on 200 000 lbf 890 kN in the J 2T 200k and 250 000 lbf 1 1 MN in the J 2T 250k the T refers to the toroidal combustion chamber Thirty years later their work was revived for use in NASA s X 33 project In this case the slightly upgraded J 2S engine machinery was used with a linear spike creating the XRS 2200 After more development and considerable testing this project was cancelled when the X 33 s composite fuel tanks repeatedly failed CSULB aerospike engine Three XRS 2200 engines were built during the X 33 program and underwent testing at NASA s Stennis Space Center The single engine tests were a success but the program was halted before the testing for the two engine setup could be completed The XRS 2200 produces 204 420 lbf 909 300 N thrust with an Isp of 339 seconds at sea level and 266 230 lbf 1 184 300 N thrust with an Isp of 436 5 seconds in a vacuum The RS 2200 Linear Aerospike Engine 5 was derived from the XRS 2200 The RS 2200 was to power the VentureStar single stage to orbit vehicle In the latest design seven RS 2200s producing 542 000 pounds force 2 410 kN each would boost the VentureStar into low earth orbit The development on the RS 2200 was formally halted in early 2001 when the X 33 program did not receive Space Launch Initiative funding Lockheed Martin chose to not continue the VentureStar program without any funding support from NASA An engine of this type is on outdoor display on the grounds of the NASA Marshall Space Flight Center in Huntsville Alabama NASA s Toroidal aerospike nozzle The cancellation of the Lockheed Martin X 33 by the federal government in 2001 decreased funding availability but aerospike engines remain an area of active research For example a milestone was achieved when a joint academic industry team from California State University Long Beach CSULB and Garvey Spacecraft Corporation successfully conducted a flight test of a liquid propellant powered aerospike engine in the Mojave Desert on September 20 2003 CSULB students had developed their Prospector 2 P 2 rocket using a 1 000 lbf 4 4 kN LOX ethanol aerospike engine This work on aerospike engines continues Prospector 10 a ten chamber aerospike engine was test fired June 25 2008 6 Nozzle performance comparison of bell and aerospike nozzle Further progress came in March 2004 when two successful tests sponsored by the NASA Dryden Flight Research Center using high power rockets manufactured by Blacksky Corporation based in Carlsbad California The aerospike nozzles and solid rocket motors were developed and built by the rocket motor division of Cesaroni Technology Incorporated north of Toronto Ontario The two rockets were solid fuel powered and fitted with non truncated toroidal aerospike nozzles Flown at the Pecos County Aerospace Development Center Fort Stockton Texas the rockets achieved apogees of 26 000 ft 7 900 m and speeds of about Mach 1 5 Small scale aerospike engine development using a hybrid rocket propellant configuration has been ongoing by members of the Reaction Research Society In 2020 the TU Dresden and Fraunhofer IWS started their CFDmSAT Project for research on additively manufactured aerospike engines A prototype has already been tested in a test cell at TU Dresden s Institute of Aerospace Engineering achieving a burn time of 30 seconds 7 Implementations EditFirefly Aerospace Edit In July 2014 Firefly Space Systems announced its planned Alpha launcher that uses an aerospike engine for its first stage Intended for the small satellite launch market it is designed to launch satellites into low Earth orbit LEO at a price of US 8 9 million much lower than with conventional launchers 8 Firefly Alpha 1 0 was designed to carry payloads of up to 400 kilograms 880 lb It uses carbon composite materials and uses the same basic design for both stages The plug cluster aerospike engine puts out 90 000 pounds force 400 kN of thrust The engine has a bell shaped nozzle that has been cut in half then stretched to form a ring with the half nozzle now forming the profile of a plug 8 This rocket design was never launched The design was abandoned after Firefly Space Systems went bankrupt A new company Firefly Aerospace has replaced the aerospike engine with a conventional engine in the Alpha 2 0 design However the company has proposed Firefly Gamma a partially reusable spaceplane with aerospike engines ARCA Space Edit In March 2017 ARCA Space Corporation announced their intention to build a single stage to orbit rocket SSTO named Haas 2CA using a linear aerospike engine The rocket is designed to send up to 100 kg into low Earth orbit at a price of US 1 million per launch 9 They later announced that their Executor Aerospike engine would produce 50 500 pounds force 225 kN of thrust at sea level and 73 800 pounds force 328 kN of thrust in a vacuum 10 In June 2017 ARCA announced that they would fly their Demonstrator3 rocket to space also using a linear aerospike engine This rocket was designed to test several components of their Haas 2CA at lower cost They announced a flight for August 2017 9 In September 2017 ARCA announced that after being delayed their linear aerospike engine was ready to perform ground tests and flight tests on a Demonstrator3 rocket 9 On December 20 2019 ARCA tested the LAS 25DA aerospike steam rocket engine for the Launch Assist System 11 KSF Space and Interstellar Space Edit Another spike engine concept model by KSF Space and Interstellar Space in Los Angeles was designed for orbital vehicle named SATORI Due to lack of funding the concept is still undeveloped 12 Rocketstar Edit Rocketstar planned to launch its 3D printed aerospike rocket to an altitude of 50 miles in February 2019 but canceled the mission three days ahead of liftoff citing safety concerns They are working on a second launch attempt 13 Pangea Aerospace Edit In November 2021 Spain based Pangea Aerospace began hot fire testing of its small scale demonstration methane oxygen aerospike engine DemoP1 14 15 After successfully testing the demonstrator DemoP1 Pangea plans to up scale to the 300kN ARCOS engine 16 Stoke Space Edit Headquartered in Kent Washington Stoke Space is building and testing a distributed architecture LH2 LOX aerospike system for its reusable second stage 17 See also EditExpanding nozzle LASRE Linear Aerospike SR 71 Experiment 1997 8 NASA for X 33 Rotary Rocket CompanyPages displaying short descriptions with no spaces Sabre Synergetic Air Breathing Rocket Engine a hybrid ramjet and rocket engine Expansion deflection nozzleReferences Edit a b c d e NASA Linear Aerospike Engine fact sheet 08 00 www nasa gov Retrieved 21 January 2020 Defusca Albert Craddock Christopher 1 November 2017 Affordable Access to Low Earth Orbit DSIAC Journals 4 4 Retrieved 16 June 2019 Aerospike Engine Homepage www hq nasa gov Pwrengineering com ww17 pwrengineering com Archived from the original on 2 April 2010 RS 2200 Astronautix com Archived from the original on 28 December 2016 Retrieved 4 February 2018 CSULB CALVEIN Rocket News and Events Archived from the original on 15 June 2008 TU Dresden Homepage tu dresden de Retrieved 23 April 2021 a b Firefly Space Systems unveils Alpha launch vehicle design with aerospike engine Gizmag com 14 July 2014 Retrieved 14 July 2014 a b c ARCA News ARCA Space ARCA Space Retrieved 30 May 2018 Haas 2CA Specs ARCA Space ARCA Space Retrieved 30 May 2018 Flight of the Aerospike Episode 34 LAS 25DA Aerospike Engine Youtube ARCA Space Archived from the original on 11 December 2021 Retrieved 5 August 2020 SATORI Space Vehicle Rocket KSF Space RocketStar ready for second suborbital flight attempt SpaceNews 27 September 2021 Retrieved 14 December 2021 Pangea Aerospace tests aerospike engine SpaceNews 20 November 2021 Retrieved 2 January 2022 Research Activities in the Development of DemoP1 A LOX LNG Aerospike Engine Demonstrator ResearchGate March 2021 Retrieved 22 December 2022 Aerospike Propulsion Pangea Aerospace Retrieved 22 December 2022 Stoke Space aims to build rapidly reusable rocket with a completely novel design Arstechnica 10 October 2022 Retrieved 13 February 2023 External links Edit Wikimedia Commons has media related to Aerospike rocket engines Aerospike Engine Advanced Engines planned for uprated Saturn and Nova boosters includes the J 2T Linear Aerospike Engine Propulsion for the X 33 Vehicle Dryden Flight Research Center Aerospike Engine Control System Features And Performance X 33 Attitude Control Using The XRS 2200 Linear Aerospike Engine Bui Trong Murray James Rogers Charles Bartel Scott Cesaroni Anthony Dennett Mike 2005 Flight Research of an Aerospike Nozzle Using High Power Solid Rockets 41st AIAA ASME SAE ASEE Joint Propulsion Conference amp Exhibit doi 10 2514 6 2005 3797 ISBN 978 1 62410 063 5 Are Aerospikes Better Than Bell Nozzles Retrieved from https en wikipedia org w index php title Aerospike engine amp oldid 1152199934, wikipedia, wiki, book, books, library,

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