A porous panel for a separator of a fuel cell includes a plate-shaped material and uneven lines repeatedly arranged on the porous panel in a direction crossing a gas flow direction. The porous panel is bent at the uneven lines such that upward and downward uneven portions are repeated, and through holes permitting passage of gas formed on opposite sides of each of the uneven lines have an uneven shape.

A porous panel for a separator of a fuel cell includes a plate-shaped material and uneven lines repeatedly arranged on the porous panel in a direction crossing a gas flow direction. The porous panel is bent at the uneven lines such that upward and downward uneven portions are repeated, and through holes permitting passage of gas formed on opposite sides of each of the uneven lines have an uneven shape.

An assembly includes a stack of SOEC/SOFC solid oxide cells, the stack having a plurality of plates stacked one on top of the other, each plate having an outer lateral surface, the plurality of plates including at least a plurality of electrochemical cells, a plurality of interconnectors, and upper and lower end plates. At least two guiding elements are configured to guide the vertical stacking of at least some of the plates of the stack. The at least two guiding elements extend vertically in a vertical direction and bear against the outer lateral surface of each of the at least some of the plates.

An assembly includes a stack of SOEC/SOFC solid oxide cells, the stack having a plurality of plates stacked one on top of the other, each plate having an outer lateral surface, the plurality of plates including at least a plurality of electrochemical cells, a plurality of interconnectors, and upper and lower end plates. At least two guiding elements are configured to guide the vertical stacking of at least some of the plates of the stack. The at least two guiding elements extend vertically in a vertical direction and bear against the outer lateral surface of each of the at least some of the plates.

A stack of SOEC/SOFC solid oxide cells includes a plurality of stacked plates and two guiding elements ensuring that the vertical stacking of at least some of the plates is guided, each plate having two guiding orifices. In a cross-sectional view, the guiding orifices are aligned in a first horizontal direction and are spaced apart by a smaller inter-orifice distance, the guiding elements being spaced apart by a greater smaller inter-element distance and the difference corresponding to the identical inner clearance for the two guiding orifices. The guiding orifices are spaced apart by a larger inter-orifice distance and the guiding elements are spaced apart by a shorter larger inter-element distance, the difference corresponding to the outer clearance, which is greater than the inner clearance.

A stack of SOEC/SOFC solid oxide cells includes a plurality of stacked plates and two guiding elements ensuring that the vertical stacking of at least some of the plates is guided, each plate having two guiding orifices. In a cross-sectional view, the guiding orifices are aligned in a first horizontal direction and are spaced apart by a smaller inter-orifice distance, the guiding elements being spaced apart by a greater smaller inter-element distance and the difference corresponding to the identical inner clearance for the two guiding orifices. The guiding orifices are spaced apart by a larger inter-orifice distance and the guiding elements are spaced apart by a shorter larger inter-element distance, the difference corresponding to the outer clearance, which is greater than the inner clearance.

A solid electrolyte fuel cell that includes a fuel electrode contact layer in contact with a fuel electrode layer and an air electrode contact layer in contact with an air electrode layer. The fuel electrode layer includes a first single metal or a first alloy, the fuel electrode contact layer includes a first conductive oxide, the air electrode layer includes a second conductive oxide, and the air electrode contact layer includes a second single metal or a second alloy.

A fuel cell stack is provided which manually increases the temperature of cells arranged in the vicinity of an end plate of the stack to improve starting performance of a fuel cell vehicle at temperatures below zero and driving performance thereof at low temperatures. The fuel cell stack realizes rapid thawing and heating functions in response to freezing of end cells when a vehicle is started at temperatures below zero, using a multilayer current collector having at least one thin collector plate which is structurally and sensitively expandable or contractible based on temperature changes.

A fuel cell stack is provided which manually increases the temperature of cells arranged in the vicinity of an end plate of the stack to improve starting performance of a fuel cell vehicle at temperatures below zero and driving performance thereof at low temperatures. The fuel cell stack realizes rapid thawing and heating functions in response to freezing of end cells when a vehicle is started at temperatures below zero, using a multilayer current collector having at least one thin collector plate which is structurally and sensitively expandable or contractible based on temperature changes.

Disclosed is an electric cell stack comprising at least a plurality of electric plates and a plurality of insulating layers, wherein the stack of the plurality of electric plates and insulating layers are alternatingly stacked in such a way that the electric plates are separated by insulating layers, and the electric plates and/or the insulating layers are aligned to each other, wherein each electric plate has a first alignment through hole and a second alignment through hole, wherein at and/or in the alignment through holes inner alignment elements are provided for aligning the electric plates and the insulating layers, wherein each inner alignment element has a base plate and an adjusting portion protruding from the base plate, wherein the adjusting portion of one alignment element extends through at least a first electric plate, a first insulating layer, a second electric plate and a second insulating layer.