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GE Partners on Hydrogen Flight Demonstrator

By September 29, 2022 6   min read  (944 words)

September 29, 2022 |

Fuel Cells Works, GE Partners on Hydrogen Flight Demonstrator

Earlier this year, CFM International, a 50-50 joint company between GE and Safran Aircraft Engines, joined Airbus to announce plans to flight test a hydrogen combustion engine. Learn more in this video with Mohamed Ali, GE Aerospace’s vice president of engineering, who explains the opportunities and challenges of hydrogen-fueled propulsion.

The race to decarbonize flight picked up speed in 2022 when CFM International and Airbus announced plans to collaborate on tests of an aircraft engine fueled by hydrogen. CFM is a 50/50 joint company between GE and Safran Aircraft Engines.

As races go, this is a long-distance one. The partners will go to work immediately, with the aim of performing the first tests around the middle of this decade. This demonstration could pave the way for an aircraft that, if all goes according to plan, would carry passengers in the mid-2030s.

“We will fly a modified engine to learn the art of the possible and to prove out the technologies,” said Mohamed Ali, vice president of engineering for GE Aerospace.

Hydrogen, which happens to be the most abundant element in the universe, produces no CO2 emissions when it burns. It has long been held up as a possible potent ally in humanity’s quest to curb carbon emissions.

But the challenges of using it as an aviation fuel are daunting. GE Aerospace’s Sean Binion, the hydrogen engine systems leader for the demonstration program, likens these challenges to those faced by the early space industry. Beyond just the technology development aspect, there are very real issues in establishing operating procedures, the development of new infrastructure and — ultimately — certifying a product. He says that it would be impossible without partnerships like this one, which comprises contributors all over the world.

The engineers at GE and Safran Aircraft Engines are working to modify a GE Passport jet engine. This includes a complete overhaul of its combustor, fuel system and controls system to make them compatible with hydrogen fuel. The group picked the Passport because of its size, advanced turbomachinery and ability to operate at the appropriate pressures and temperatures for the flight platform.

When flight tests begin around the mid-2020s, the modified engine will be mounted on the rear top of the fuselage on an Airbus A380, the world’s largest commercial airliner, powered by its original four engines. But the new configuration will allow the team to test the modified hydrogen-powered engine’s emissions, including contrails, and monitor them separately.

Fuel Cells Works, GE Partners on Hydrogen Flight Demonstrator

A deconstructed Passport engine like the one that engineers will be modifying for hydrogen combustion testing.

Massimo Varriani, European system leader for the hydrogen program at Avio Aero, a GE business, says “the purpose of the project is to demonstrate the technology,” and the resulting prototype will later be scalable to work with different sizes of engines and different types of aircraft applications. Ultimately, it could be applied to various designs like Airbus’s three ZEROe concepts, which include a turbofan engine, a turboprop and a futuristic blended-wing design. “What is important is that we demonstrate we can fly with an engine that is burning just hydrogen, we have the storage capability of hydrogen in the aircraft and we have a system that is capable of distributing the hydrogen fuel into the combustor with the proper characteristics,” Varriani says.

Storing the hydrogen onboard presents another big engineering challenge. Because H2 naturally exists as a gas — which, if carried in sufficient amounts for passenger jet travel, would take up more storage space than the entire plane — it will need to be stored in liquid form, which means cooling it to about minus 253 Celsius (423 degrees Fahrenheit). That liquid hydrogen will then need to be vaporized into gas to be used as fuel — this will mean that certain parts of the engine could see temperature differences of some 1,500 degrees Fahrenheit.

It’s no small task, but Binion believes the team is up to the challenge: “CFM is committed to working with our partners to decarbonize aviation,” he says. “And our team is passionate about succeeding on this project. It’s both exciting and gratifying … We’re very tangibly inventing and executing on a key element of the future of more sustainable flight.”

In October 2021, the Air Transport Action Group (ATAG) announced a goal of achieving net-zero carbon emissions in the aviation industry by 2050, by helping deliver the technologies to make that possible. CFM, one of the signatories to that pledge, has rolled out ambitious plans in recent years.

CFM’s RISE (Revolutionary Innovation for Sustainable Engines) Program, announced in June 2021, aims to develop the technology that could lead to an engine that would use 20% less fuel and produce 20% fewer CO2 emissions than the most efficient jet engines today using conventional jet fuel. Additionally, a configuration compatible with hydrogen technology developed as part of the CFM and Airbus combustion demonstration would result in zero carbon emissions during flight.

But for airlines to move their fleets over to H2, there will need to be a concerted effort to produce more H2 — which can be done in a more renewable fashion if the power used to produce it is derived from sources like wind and solar. The good news is, GE Gas Power already has years of experience in using hydrogen in power plants; its turbines have logged more than 8 million operating hours running on blends of hydrogen, including green hydrogen in several recent demonstration projects. The knowledge and experience from those projects will be one of many instances of cross-pollination within GE and across the partnership that Binion says are reason for optimism.

Fuel Cells Works, GE Partners on Hydrogen Flight Demonstrator

An artist’s rendering of hydrogen fuel being burned in the combustor of a jet engine.

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