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British space plane developer claims huge engine advance

A small British company with a dream of building a reusable space plane has won an important endorsement from the European Space Agency after completing key tests on its novel engine technology.
The Skylon concept vehicle consists of a slender fuselage containing propellant tankage and payload bay, with delta wings attached along the fuselage carrying the Sabre engines in axisymmetric nacelles on the wingtips. The vehicle takes off and lands horizontally on its own undercarriage.
The Skylon concept vehicle consists of a slender fuselage containing propellant tankage and payload bay, with delta wings attached along the fuselage carrying the Sabre engines in axisymmetric nacelles on the wingtips. The vehicle takes off and lands horizontally on its own undercarriage.Adrian Mann
/ Source: Reuters

A small British company with a dream of building a reusable space plane has won an important endorsement from the European Space Agency after completing key tests on its novel engine technology.

Reaction Engines believes that its Sabre engine, which would operate like a jet engine in the atmosphere and like a rocket in space, could displace rockets for space access and transform air travel by bringing any destination on Earth to no more than four hours away.

That ambition was given a boost on Wednesday by ESA, which has acted as an independent auditor on the Sabre test program. "ESA are satisfied that the tests demonstrate the technology required for the Sabre engine development," the agency's head of propulsion engineering, Mark Ford, told a news conference.

"One of the major obstacles to a reusable vehicle has been removed," he said. "The gateway is now open to move beyond the jet age."

The space plane, dubbed Skylon, only exists on paper. What the company has right now is a heat exchanger that is able to cool air sucked into the engine at high speed from 1,000 degrees Celsius to minus 150 degrees (1,800 degrees Fahrenheit to 238 below zero F) in one-hundredth of a second.

This core piece of technology solves one of the constraints that limit jet engines to a top speed of about 2.5 times the speed of sound, which Reaction Engines believes it could double.

Shrouded in secrecy
With the Sabre engine in jet mode, the air has to be compressed before being injected into the engine's combustion chambers. Without pre-cooling, the heat generated by compression would make the air hot enough to melt the engine.

The challenge for the engineers was to find a way to cool the air quickly without frost forming on the heat exchanger, which would clog it up and keep it from working.

Using a nest of fine pipes that resemble a large wire coil, the engineers say they have managed to get around this fatal problem that would normally follow from such rapid cooling of the moisture in atmospheric air.

They are tight-lipped on exactly how they managed to do it.

"We are not going to tell you how this works," said the company's chief designer Richard Varvill, who started his career at the military engine division of Rolls-Royce. "It is our most closely guarded secret."

The company has deliberately avoided filing patents on its heat exchanger technology to conceal the details of how it works — particularly the method for preventing the buildup of frost.

The Sabre engine could take a plane to five times the speed of sound and an altitude of 25 kilometers (15 miles), about 20 percent of the speed and altitude needed to reach orbit. For space access, the engines would then switch to rocket mode to do the remaining 80 percent.

$400 million needed
Reaction Engines believes Sabre is the only engine of its kind in development and the company now needs to raise about 250 million pounds ($400 million) to fund the next three-year development phase, in which it plans to build a small-scale version of the complete engine.

Chief executive Tim Hayter believes the company could have an operational engine ready for sale within 10 years if it can raise the development funding.

The company reckons the engine technology could win a healthy chunk of four key markets together worth $112 billion a year, including space access, hypersonic air travel, and modified jet engines that use the heat exchanger to save fuel.

The fourth market is unrelated to aerospace. Reaction Engines believes the technology could also be used to raise the efficiency of so-called multistage flash desalination plants by 15 percent. These plants, located largely in the Middle East, use heat exchangers to distill water by flash-heating sea water into steam in multiple stages.

The firm has so far received 90 percent of its funding from private sources, mainly rich individuals including chairman Nigel McNair Scott, the former mining industry executive who also chairs property developer Helical Bar.

Chief executive Tim Hayter told Reuters he would welcome government investment in the company, mainly because of the credibility that would add to the project.

But the focus will be on raising the majority of the $400 million it needs now from a mix of institutional investors, high-net-worth individuals and possibly potential partners in the aerospace industry.

How the Sabre engine works
Sabre produces thrust by burning hydrogen and oxygen, but inside the atmosphere it would take that oxygen from the air, reducing the amount it would have to carry in fuel tanks for rocket mode, cutting weight and allowing Skylon to go into orbit in one stage.

Scramjets on test vehicles like the U.S. Air Force Waverider also use atmospheric air to create thrust, but they have to be accelerated to their operating speed by normal jet engines or rockets before they kick in. The Sabre engine can operate from a standing start.

If the developers are successful, Sabre would be the first engine in history to send a vehicle into space without using disposable, multistage rockets.

Skylon is years away, but in the meantime the technology is attracting interest from the global aerospace industry and governments because it effectively doubles the technical limits of current jet engines and could cut the cost of space access.

The heat exchanger technology could also be incorporated into a new jet engine design that could cut 5 to 10 percent — or $10 billion to $20 billion — off airline fuel bills. That would be significant in an industry where incremental efficiency gains of one percent or so, from improvements in wing design for instance, are big news.