A fuel cell including at least one membrane, at least one anode electrode layer, at least one cathode electrode layer, at least two gas diffusion layers and at least two flow field structures. The at least one membrane is arranged between one anode electrode layer and one cathode electrode layer, forming a membrane electrode assembly and defining an active area. One gas diffusion layer is arranged adjacent to each electrode layer. One flow field structure is arranged adjacent to each gas diffusion layer. Each flow field structure includes at least three fuel manifolds, at least three oxidant manifolds and at least three coolant manifolds. The fuel cell includes at least two active areas and in that at least one fuel manifold, at least one oxidant manifold and at least one coolant manifold is arranged between the at least two active areas.

A solid oxide fuel cell includes a fuel cell main body which includes a cathode layer, a solid electrolyte layer, and an anode layer and which has a power generation function; a connector disposed to face one electrode layer of the cathode layer and the anode layer; a current collector which is disposed between the one electrode layer and the connector and which is in contact with a surface of the one electrode layer and a surface of the connector, the surfaces facing each other, to thereby electrically connect the one electrode layer and the connector; and a groove provided in a portion of a surface of the one electrode layer, which surface is located on the side where the one electrode layer is in contact with the current collector, the portion of the surface being not in contact with the current collector.

A solid oxide fuel cell includes a fuel cell main body which includes a cathode layer, a solid electrolyte layer, and an anode layer and which has a power generation function; a connector disposed to face one electrode layer of the cathode layer and the anode layer; a current collector which is disposed between the one electrode layer and the connector and which is in contact with a surface of the one electrode layer and a surface of the connector, the surfaces facing each other, to thereby electrically connect the one electrode layer and the connector; and a groove provided in a portion of a surface of the one electrode layer, which surface is located on the side where the one electrode layer is in contact with the current collector, the portion of the surface being not in contact with the current collector.

A module for an HTE reactor or an SOFC fuel cell, the module including a circuit for the circulation of a gas, in addition to the reactive gases required for the electrolysis reaction or the reverse reaction in an SOFC cell, the circuit enabling, during the operation under pressure, the additional gas to equalise, on one side of the glass- and/or vitroceramic-based seals, the pressure of the reactive gases generated on the other side.

Systems and methods for sintering and conditioning fuel cell stacks utilizing channel guides, baffles, and internal compression systems are provided. Sintering and conditioning may be performed utilizing a fuel cell column cartridge assembly and fuel cell stacks may be sintered and conditioned at the system level during the same annealing cycle on the same support.

A cell includes an element portion and a metal member. The metal member includes a first gas-flow passage and a second gas-low passage, and supports the element portion. First gas flows through the first gas-flow passage. Second gas flows through the second gas-flow passage.

A fuel cell stack and inspection method, the fuel cell stack including fuel cells disposed in a stack and interconnects disposed between the fuel cells. Each fuel cell includes an electrolyte, an anode disposed on a first side of the electrolyte, a cathode disposed on an opposing second side of an electrolyte, and a witness mark disposed on the first side of the electrolyte. Each interconnect includes first ribs disposed on air side of the interconnect and at least partially defining oxidant channels, and second ribs disposed on an opposing fuel side of the interconnect and at least partially defining fuel channels. The witness mark of each fuel cell is visible from outside of the stack when the cathode directly faces the air side of an adjacent interconnect.

A fuel cell stack and inspection method, the fuel cell stack including fuel cells disposed in a stack and interconnects disposed between the fuel cells. Each fuel cell includes an electrolyte, an anode disposed on a first side of the electrolyte, a cathode disposed on an opposing second side of an electrolyte, and a witness mark disposed on the first side of the electrolyte. Each interconnect includes first ribs disposed on air side of the interconnect and at least partially defining oxidant channels, and second ribs disposed on an opposing fuel side of the interconnect and at least partially defining fuel channels. The witness mark of each fuel cell is visible from outside of the stack when the cathode directly faces the air side of an adjacent interconnect.

Disclosed are a separator for fuel cells capable of minimizing the volume of a system and the use of sealants, and a stack for fuel cells, more particularly, a stack for solid oxide fuel cells, including the same. Specifically, by adding a metal sheet having a specific shape, position and size to the separator, the stress applied to the sealant can be uniformized, and thus the oxidizing agent and fuel can be separated and electrically isolated using only a piece of sealant. Therefore, the stack for fuel cells is characterized in that there is no variation in temperature, reactant concentration, power, or the like between respective unit cells, so delamination and microcracks do not occur, the volume is minimized, and the power density per unit volume is very high.

A manifold includes first and second manifold main bodies. The first manifold main body includes a gas supply chamber that is connected to a first gas channel and the second manifold main body includes a gas collection chamber that is connected to a second gas channel. The first manifold main body includes a top plate, a first bottom plate, and a first side plate. The top plate includes a first through hole for connecting the first gas channel and the gas supply chamber. The second manifold main body includes the top plate, a second bottom plate, and a second side plate. The top plate also includes a second through hole for connecting the second gas channel and the gas collection chamber. The first bottom plate and the second bottom plate are constituted by members that are separate from each other.