UK engineers developing a novel propulsion system say their technology has passed another key milestone.
The Sabre air-breathing rocket engine is designed to drive space planes to orbit and take airliners around the world in just a few hours.
To work, it needs to manage very high temperature airflows, and the team at Reaction Engines Ltd has developed a heat-exchanger for the purpose.
This key element has just demonstrated an impressive level of performance.
It has shown the ability to handle the simulated conditions of flying at more than three times the speed of sound.
It did this by successfully quenching a 420C stream of gases in less than 1/20th of a second.
The REL group is confident its "pre-cooler" technology can now go on to show the same performance in conditions that simulate flying above five times the speed of sound, or Mach 5.
That would mean rapidly dumping the energy in a 1,000-degree airflow.
"We're now able to prove many of the claims we've been making as a business, backed up by very high-quality data," REL's CEO Mark Thomas told BBC News.
"In this most recent experiment, we've near-instantaneously transferred 1.5 Megawatts of heat energy - the equivalent of 1,000 homes' worth of heat energy."
The testing was conducted at a dedicated facility at the Colorado Air and Space Port in the US.
Sabre can be thought of as a cross between a jet engine and a rocket engine.
At slow speeds and at low altitude, it would behave like a jet, burning its fuel in a stream of air scooped from the atmosphere.
At high speeds and at high altitude, it would then transition to full rocket mode, combining the fuel with a small supply of oxygen the vehicle had carried aloft.
The early air-breathing approach would deliver substantial weight savings, and allow a space plane, for example, to go straight to orbit without throwing away propellant stages on the way up, as rockets do now.
But the concept brings with it an immense heat challenge.
The faster the flow of air into the engine's intake during the high-speed ascent, the higher the temperature.
And the heat would rise still further once the flow was slowed and compressed prior to entering the combustion chambers.
Such conditions would ordinarily melt the insides of the engine.
Sabre's pre-cooler seeks to solve this problem by efficiently, and swiftly, extracting the heat by first passing the intake gases through a tightly packed array of fine tubing. This tubing is fed with chilled helium.
In 2012, REL put the pre-cooler in front of a viper jet engine and sucked ambient air through the heat-exchanger. The gas stream immediately dropped to minus-150C.
Now, the company has flipped the set-up, putting the jet engine from an old F-4 Phantom fighter-bomber in front of the pre-cooler to drive hot gases directly across the piping array.
The completed Colorado experiment replicates the thermal conditions corresponding to flight at Mach 3.3, the record-breaking speed at which the American SR-71 Blackbird spy plane used to operate. Importantly, though, the pre-cooler took out all the heat.
"This technology has wide application, not just in the immediate, obvious domain of high-speed flight but across the aerospace industry more generally, and into more commercial applications - anywhere there's a significant heat-management challenge and you're looking for ultra-lightweight, miniaturised, high-performance solutions," Mr Thomas said.
The Colorado tests continue. Meanwhile, back in England, REL is progressing towards a demonstration of the core part of the engine, expected to get under way next year.
This core combustion section recently passed its preliminary design review under the eye of propulsion experts at the European Space Agency. Esa has been brought in by the UK government to act as a technical auditor on the project.
The Oxfordshire company is developing Sabre with the support of BAE Systems, Rolls-Royce and Boeing. All are keen to see the many years of refinement on the engine concept finally come to fruition.
Hypersonic flight technology just passed a ‘hugely significant’ milestone
A rendering of a hypersonic vehicle in flight.
Engineers working on a propulsion system to enable hypersonic air travel say they have passed a development milestone.
U.K.-based Reaction Engines is developing technology for Synergetic Air-Breathing Rocket Engines (SABRE), which could one day allow aircraft to fly up to five times faster than the speed of sound — that’s Mach 5 or 3,836 miles per hour.
At that speed, hypersonic flights between London and Australia could be over in just four-and-a-half hours.
While some commercial plane makers are racing to bring back supersonic jets, Boeing has gone further than many of its competitors by unveiling a design for a hypersonic aircraft that could potentially travel five times quicker.
But for those speeds to be possible, the futuristic engines need to process air flows with extremely high temperatures. Now Reaction Engines has revealed that its precooler component – designed to manage extreme heat – has successfully handled temperatures of 420 degrees Celsius, matching the conditions it would face when reaching Mach 3.3 speeds. At that speed, an aircraft would be traveling three times faster than the speed of sound and 50 percent faster than Concorde.
The test took place at Reaction Engines’ facility at the United States’ Colorado Air and Space Port. They were the first phase of an extensive trial program, which will eventually see the precooler exposed to temperatures hotter than 1,000 degrees Celsius – the conditions expected during Mach 5 hypersonic flight.
In space rocket mode, the engines are being designed to speed a craft up to Mach 25.
Over the last four years, Reaction Engines has secured more than £100 million ($130 million) in investment from backers including BAE Systems, Rolls-Royce, and Boeing’s venture capital arm. The firm has also received a £60 million ($78 million) funding commitment from the U.K. Government.
Mark Thomas, Reaction Engines CEO, said in a press release Monday that the results were unparalleled and a “hugely significant milestone.”
“This provides an important validation of our heat exchanger and thermal management technology portfolio, which has application across emerging areas such as very high-speed flight, hybrid electric aviation and integrated vehicle thermal management,” he said.