Space
True Spaceplane Enabling Radically Superior Engine Technology Receives Funding
Mark Hoffman
First Posted: Jul 18, 2013 05:22 PM EDT
The UK government has announced plans to invest in the development of an air-breathing rocket engine – intended for a single-stage-to-orbit spaceplane – following the ESA-managed feasibility testing of essential technology.
The £60 million investment, provided through the UK Space Agency, will back technical improvements leading to construction of a prototype Synergistic Air-Breathing Rocket Engine, or SABRE.
Designed by UK company Reaction Engines Ltd, this unique engine will use atmospheric air in the early part of the flight before switching to rocket mode for the final ascent to orbit -- this is achieved by cooling down and compressing incoming air until it is nearly liquefied, like the oxygen used in conventional rockets.
The concept paves the way for true spaceplanes – lighter, reusable and able to fly from conventional runways.
Reaction Engines plans for SABRE to power a 84 m-long pilotless vehicle called Skylon, which would do the same job as today’s rockets while operating like an aeroplane, potentially revolutionising access to space.
The investment decision followed the success of ESA-managed tests of a key element of the SABRE design, a precooler to chill the hot air entering the engine at hypersonic speed, in Reaction Engines’ Oxfordshire headquarters back in November 2012.
“Ambient air comes in and is cooled down to below freezing in a fraction of a second,” explained Mark Ford, head of ESA’s propulsion section. “These types of heat exchangers exist in the real world but they’re the size of a factory.
“The key part of this is that Reaction Engines has produced something sufficiently light and compact that it can be flown.
“The idea behind the engine is that the vehicle flies to about Mach 5 in the lower atmosphere using airbreathing before it switches internal liquid oxygen for the rest of its flight to orbit.
“At that speed, the air is coming in extremely fast. You need to slow it down in order to burn it in the engine, and doing so will raise the temperature of the air to about a thousand degrees, which can exceed engine material temperature limits.
“Hence the concept of the precooler is to cool the air down to a temperature that is then usable by the engine.
The idea has been around since the 1950s but this is the first time anyone has managed to achieve a working system. Nobody else has this technology, so Europe has a real technological lead here.”
Having passed vital tests in November 2012, it is the first time a heat exchanger that is light and efficient enough to go into space has been developed. By managing the hot air entering it at high speeds, SABRE would be able to get some of the oxygen it needs from the air rather than it having to be stored onboard the spaceplane. This advantage enables a spaceplane to fly lighter from the outset and to make a single leap to orbit, rather than using and dumping propellant stages on the ascent - as is the case with current expendable rockets. It is expected that this would make access to space 50 times cheaper, although prototypes will not fly before the 2020's. -- with material from ESA
See Now:
NASA's Juno Spacecraft's Rendezvous With Jupiter's Mammoth Cyclone
TagsSpaceplane ©2024 ScienceWorldReport.com All rights reserved. Do not reproduce without permission. The window to the world of science news.
More on SCIENCEwr
First Posted: Jul 18, 2013 05:22 PM EDT
The UK government has announced plans to invest in the development of an air-breathing rocket engine – intended for a single-stage-to-orbit spaceplane – following the ESA-managed feasibility testing of essential technology.
The £60 million investment, provided through the UK Space Agency, will back technical improvements leading to construction of a prototype Synergistic Air-Breathing Rocket Engine, or SABRE.
Designed by UK company Reaction Engines Ltd, this unique engine will use atmospheric air in the early part of the flight before switching to rocket mode for the final ascent to orbit -- this is achieved by cooling down and compressing incoming air until it is nearly liquefied, like the oxygen used in conventional rockets.
The concept paves the way for true spaceplanes – lighter, reusable and able to fly from conventional runways.
Reaction Engines plans for SABRE to power a 84 m-long pilotless vehicle called Skylon, which would do the same job as today’s rockets while operating like an aeroplane, potentially revolutionising access to space.
“Ambient air comes in and is cooled down to below freezing in a fraction of a second,” explained Mark Ford, head of ESA’s propulsion section. “These types of heat exchangers exist in the real world but they’re the size of a factory.
“The key part of this is that Reaction Engines has produced something sufficiently light and compact that it can be flown.
“The idea behind the engine is that the vehicle flies to about Mach 5 in the lower atmosphere using airbreathing before it switches internal liquid oxygen for the rest of its flight to orbit.
“At that speed, the air is coming in extremely fast. You need to slow it down in order to burn it in the engine, and doing so will raise the temperature of the air to about a thousand degrees, which can exceed engine material temperature limits.
“Hence the concept of the precooler is to cool the air down to a temperature that is then usable by the engine.
The idea has been around since the 1950s but this is the first time anyone has managed to achieve a working system. Nobody else has this technology, so Europe has a real technological lead here.”
Having passed vital tests in November 2012, it is the first time a heat exchanger that is light and efficient enough to go into space has been developed. By managing the hot air entering it at high speeds, SABRE would be able to get some of the oxygen it needs from the air rather than it having to be stored onboard the spaceplane. This advantage enables a spaceplane to fly lighter from the outset and to make a single leap to orbit, rather than using and dumping propellant stages on the ascent - as is the case with current expendable rockets. It is expected that this would make access to space 50 times cheaper, although prototypes will not fly before the 2020's. -- with material from ESA
See Now: NASA's Juno Spacecraft's Rendezvous With Jupiter's Mammoth Cyclone