FIELD: electricity.
SUBSTANCE: group of inventions relates to metal supported solid oxide fuel cells. Said method for forming a metal supported solid oxide fuel cell comprises applying a green anode layer to a metal substrate, said layer containing nickel oxide, copper oxide and rare earth-doped ceria, wherein nickel oxide, copper oxide and rare earth-doped ceria are ground into a powder with particle size distribution d90 in the range of 0.1 to 4 mcm; firing the green anode layer to form a composite material containing nickel and copper oxides, as well as rare-doped ceria; providing an electrolyte and providing a cathode. There is also a solid oxide fuel cell with a metal support, as well as a stack of fuel cells and the use of a fuel cell.
EFFECT: group of inventions makes it possible to increase the stability of the fuel cell with respect to multiple reduction-oxidation cycles.
16 cl, 8 dwg
| Title | Year | Author | Number |
|---|---|---|---|
| METHOD FOR FORMING METAL SUPPORTED SOLID OXIDE FUEL CELLS | 2014 |
|
RU2670423C2 |
| ANODE FOR SOLID OXIDE FUEL CELL | 2017 |
|
RU2743000C2 |
| FUEL CELL | 2017 |
|
RU2737141C2 |
| ELECTROLYTE FORMATION METHOD | 2016 |
|
RU2699815C2 |
| ELECTROLYTE FORMATION METHOD | 2016 |
|
RU2696618C2 |
| METHOD FOR PRODUCING POROUS STAINLESS STEEL SUPPORT FOR SOLID OXIDE FUEL CELLS AND POROUS SUPPORT MADE BY SAID METHOD | 2023 |
|
RU2812432C1 |
| CERAMIC-METAL ANODE STRUCTURE (ITS VERSIONS) AND ITS APPLICATION | 2008 |
|
RU2480863C2 |
| CERAMIC ANODE STRUCTURE (ITS VERSIONS) AND ITS APPLICATION | 2008 |
|
RU2479893C2 |
| SOLID-OXIDANT FUEL CELL USING CERAMIC ANODE | 2003 |
|
RU2323506C2 |
| REVERSIBLE SOLID OXIDE FUEL ELEMENT (ITS VERSIONS) | 2008 |
|
RU2480865C2 |
