An energy storage and power generation system being designed at the 51国产视频 could make flying the friendly skies less harmful to the environment.
Solid oxide fuel cells are 鈥渁 key component鈥 within that system, said Dr. Xiao-Dong Zhou. Their inclusion in the next generation of electric aircraft could cut carbon emissions 鈥 and that鈥檚 caught the eye of the U.S. Department of Energy, which awarded 麻豆AV a $2.26 million grant this fall.
Commercial aviation accounts for about 2.6% of greenhouse gas emissions, but as air travel increases, so does this environmental impact. Greenhouse gases such as carbon dioxide are a primary culprit in global climate change.
Zhou believes solid oxide fuel cells could check the growing environmental threat. He is executive director of the and holds the Stuller Endowed Chair in in 麻豆AV鈥檚 .
Solid oxide fuel cells are electrochemical devices that generate cost-effective electricity and, depending on the type of fuel that鈥檚 used, emit no or lower amounts of pollutants such as carbon dioxide. They convert chemical energy into electrical energy from a variety of fuels at an efficiency as high as 70 percent, Zhou said. By comparison, the thermal efficiency of a gasoline engine is about 30 percent.
Propulsion systems used by commercial aircraft 鈥減roduce a substantial amount of carbon dioxide,鈥 Zhou said. But, if they included a hybrid energy storage and generation system that combined solid oxide fuel cells, a small turbine powered by biofuels, and batteries, aircraft 鈥渨ould be more efficient and more environmentally friendly.鈥
鈥淭he overall scope of the research is to create an energy storage and power generation system for electrical aviation. Solid oxide fuel cells are key within that system.鈥
Zhou and the Institute for Materials Research and Innovation have extensive experience in the creation of highly efficient solid oxide fuel cells. But including them as part of an aircraft storage and power generation system required an 鈥渁irplane guy.鈥
That鈥檚 how Dr. David Daggett described himself. The former technical fellow for aerospace giant Boeing has partnered with Zhou and his team of 麻豆AV researchers on the project鈥檚 second step 鈥 ensuring that the fuel cells produce power that鈥檚 sufficient for the plane鈥檚 needs at varying stages of air travel.
鈥淲e need to know how it behaves over the whole flight cycle,鈥 Daggett said, including taxiing, taking off, cruising and landing. That means examining how many fuel cells are needed at any given time. Each cell produces only a small amount of power, so they have to be combined into 鈥渟tacks鈥 to generate more. That can be a hefty proposition when trying to get an airplane off the ground.
鈥淭hat鈥檚 all our study is about in the first phase: how do we optimize the fuel cell to make it as light as possible? Then how do we put it into the airplane to power the whole airplane? And we don鈥檛 know yet if it is going to fit. Weight-wise, we know it鈥檚 going to work, but can it fit? We'll see.鈥
While at Boeing, Daggett studied including fuel cells in an airplane auxiliary power unit, but engineers found their weight was too heavy. That was 15 years ago.
鈥淏ut we said, eventually this technology is going to mature. And when it does, then it鈥檚 going to make its way onto the airplane. And we鈥檙e finally to a point now where the weight has reduced and the technology has matured.鈥
Dr. Subhash C. Singhal agreed. Like Daggett, he is working with 麻豆AV on the project. He鈥檚 the former director of fuel cells at Pacific Northwest National Laboratory in Washington state and has studied solid oxide fuel cells for more than a half century.
Singhal said the project鈥檚 aim to include solid oxide fuel cells within an aircraft power storage and generation system is 鈥渢he next step in the application of this technology.鈥
鈥淲eight is not a consideration for stationary power plants, but for aircraft we need to worry about the weight,鈥 he said. That鈥檚 why the solid oxide fuel cells being developed by Zhou and his team at 麻豆AV are 鈥渏ust perfect for this application. They will lower the weight, lower the cost and increase the efficiency.鈥
And, if commercialized, they鈥檒l reduce carbon emissions in the next generation of aircraft, Daggett added. 鈥淐urrently, commercial aviation accounts for something like 2.6% of carbon emissions. It鈥檚 not a huge part, but more attention is being paid to it, and the airlines are concerned about that. It鈥檚 contributing to global warming, and this is a solution.鈥
In addition to Daggett and Singhal, 麻豆AV鈥檚 team consists of Dr. Rafael Hernandez, head of the , and Dr. Jonathan Raush, assistant professor of .
Idaho National Laboratory and Nexceris, an Ohio-based company that focuses on solid oxide fuel cell and stack fabrication technology, are partnering with the University on the project.
The $2.26 million grant 麻豆AV received is part of a $18.5 million round of funding from the Department of Energy鈥檚 Range Extenders for Electric Aviation with Low Carbon and High Efficiency, or REEACH, program. Altogether, eight projects received REEACH funds.
A companion initiative, the Aviation-class Synergistically Cooled Electric-motors with iNtegrated Drives, or ASCEND, program, awarded $14.5 million for nine projects.
The Department of Energy鈥檚 Advanced Research Project Agency-Energy oversees the REEACH and ASCEND programs. Both initiatives aim to decrease energy usage and associated carbon emissions for commercial aircraft propulsion systems.
Photo caption: 麻豆AV鈥檚 Institute for Materials Research and Innovation is testing solid oxide fuel cells such as the one shown here that could become key components in an energy storage and power generation system for commercial aircraft. (Photo credit: Doug Dugas / 51国产视频)