A lamellar structure graphite foil is used as a material for a separator for a fuel cell, and a hydrophobic layer is formed by impregnation on flow-field channels of the graphite foil. Such a separator is manufactured by forming the flow field channel by etching the graphite foil formed with the mask pattern thereon and forming a hydrophobic layer by impregnation. According to such a separator, performance of a fuel cell stack is enhanced and the manufacturing process of a separator is simplified.

A lamellar structure graphite foil is used as a material for a separator for a fuel cell, and a hydrophobic layer is formed by impregnation on flow-field channels of the graphite foil. Such a separator is manufactured by forming the flow field channel by etching the graphite foil formed with the mask pattern thereon and forming a hydrophobic layer by impregnation. According to such a separator, performance of a fuel cell stack is enhanced and the manufacturing process of a separator is simplified.

A reaction cell for a flow battery having flow channels positioned within a recess of a non-porous and non-brittle housing that is also a dielectric. Positioning the flow channels within the recess eliminates the need for end plates, gaskets, and insulators of conventional designs. A current collector and an electrode within the recess have areas approximately equal to the area of the recess such that they fit within the recess and maximize the contact area between them.

A reaction cell for a flow battery having flow channels positioned within a recess of a non-porous and non-brittle housing that is also a dielectric. Positioning the flow channels within the recess eliminates the need for end plates, gaskets, and insulators of conventional designs. A current collector and an electrode within the recess have areas approximately equal to the area of the recess such that they fit within the recess and maximize the contact area between them.

A redox flow battery includes a flow path frame provided with a flow path conveying an electrolyte introduced into a fixing frame having a flow path for introducing and discharging an electrolyte supplied from outside. The flow path frame is provided with an inflow path connected to the flow path of the fixing frame and an outflow path discharging the electrolyte to an impregnation part conveying the electrolyte to a reaction surface of a membrane, thereby preventing leakage of the electrolyte that is caused by a difference between supply pressure and circulation pressure of the electrolyte.

Fuel cell stack assemblies (100) have a positive end plate (200) and a negative end plate (300), The end plates (200, 300) can be formed from a central structural element (220, 320) with an insulating end plate cover (210, 310) and an insulating end plate manifold (230, 330). A plurality of cathode plates (150) and a plurality of fuel cell assemblies (250) can be arranged in a stack having an alternating pattern of cathode plates (150) and fuel cell assemblies (250), with the positive end plate (200) and the negative end plate (300) provided on either end of the stack of cathode plates and fuel cell assemblies.

Fuel cell stack assemblies (100) have a positive end plate (200) and a negative end plate (300), The end plates (200, 300) can be formed from a central structural element (220, 320) with an insulating end plate cover (210, 310) and an insulating end plate manifold (230, 330). A plurality of cathode plates (150) and a plurality of fuel cell assemblies (250) can be arranged in a stack having an alternating pattern of cathode plates (150) and fuel cell assemblies (250), with the positive end plate (200) and the negative end plate (300) provided on either end of the stack of cathode plates and fuel cell assemblies.

A fuel cell stack includes: a cell stacked body in which a plurality of fuel cells are stacked in multiple layers; and an end plate by which the plurality of fuel cells are fastened, the end plate including an open end plate disposed at one end of the cell stacked body and a closed end plate disposed at another end of the cell stacked body, wherein the open end plate includes a gas inlet delivering a reactant gas supplied from an outside of the fuel cell stack to the cell stacked body, a gas outlet discharging the reactant gas having passed through the cell stacked body to the outside of the fuel cell stack, and a bypass channel connecting the gas inlet to the gas outlet to guide condensed water introduced to the gas inlet to the gas outlet, the bypass channel partially curved to allow the condensed water to be collected.

A fuel cell stack includes: a cell stacked body in which a plurality of fuel cells are stacked in multiple layers; and an end plate by which the plurality of fuel cells are fastened, the end plate including an open end plate disposed at one end of the cell stacked body and a closed end plate disposed at another end of the cell stacked body, wherein the open end plate includes a gas inlet delivering a reactant gas supplied from an outside of the fuel cell stack to the cell stacked body, a gas outlet discharging the reactant gas having passed through the cell stacked body to the outside of the fuel cell stack, and a bypass channel connecting the gas inlet to the gas outlet to guide condensed water introduced to the gas inlet to the gas outlet, the bypass channel partially curved to allow the condensed water to be collected.

A fuel cell stack at least includes a stack body formed by stacking a plurality of power generation cells in a stacking direction and a first dummy cell provided at one end of the stack body in the stacking direction. The power generation cell includes a membrane electrode assembly. The first dummy cell includes a dummy assembly formed by stacking together three electrically conductive porous bodies each having a different surface size, a dummy resin frame member formed around the dummy assembly, and dummy separators.