A fuel cell is disclosed. The fuel cell includes a cell stack including a plurality of unit cells stacked in a first direction, an enclosure surrounding side portions of the cell stack and including at least one opening to expose at least one of opposite end portions of the cell stack therethrough, first and second end plates respectively disposed at the opposite end portions of the cell stack, and a gasket disposed between a target end plate disposed in the at least one opening in the enclosure, among the first and second end plates, and the enclosure in order to seal the cell stack.

A fuel cell is disclosed. The fuel cell includes a cell stack including a plurality of unit cells stacked in a first direction, an enclosure surrounding side portions of the cell stack and including at least one opening to expose at least one of opposite end portions of the cell stack therethrough, first and second end plates respectively disposed at the opposite end portions of the cell stack, and a gasket disposed between a target end plate disposed in the at least one opening in the enclosure, among the first and second end plates, and the enclosure in order to seal the cell stack.

A single cell includes a linear sealing portion bonded to a pair of gas separators, the sealing portion being provided between the gas separators. A fuel cell in which a plurality of single cells is laminated includes: a gasket provided between the single cells adjacent to each other; a first manifold communicating with an inside-cell gas passage; and a second manifold communicating with an inter-cell refrigerant passage. The gasket includes a first gasket placed to surround the outer periphery of the first manifold and configured to seal the first manifold, and a second gasket configured to seal the second manifold and an inter-cell refrigerant passage. When the fuel cell is viewed from the laminating direction, the first gasket, the sealing portion, and the second gasket are placed in this order from the first manifold toward the second manifold between the first manifold and the second manifold.

A single cell includes a linear sealing portion bonded to a pair of gas separators, the sealing portion being provided between the gas separators. A fuel cell in which a plurality of single cells is laminated includes: a gasket provided between the single cells adjacent to each other; a first manifold communicating with an inside-cell gas passage; and a second manifold communicating with an inter-cell refrigerant passage. The gasket includes a first gasket placed to surround the outer periphery of the first manifold and configured to seal the first manifold, and a second gasket configured to seal the second manifold and an inter-cell refrigerant passage. When the fuel cell is viewed from the laminating direction, the first gasket, the sealing portion, and the second gasket are placed in this order from the first manifold toward the second manifold between the first manifold and the second manifold.

An elastomeric cell frame for a fuel cell according to an embodiment of the present disclosure includes, as a cell frame constituting a unit cell of a fuel cell, an insert including a membrane electrode assembly having an anode formed on one surface of a polymer electrolyte membrane, and having a cathode formed on the other surface thereof, and a pair of gas diffusion layers disposed on both surfaces thereof; and an elastomeric frame disposed to surround the rim of the insert in the outer region of the insert, and formed with a discharge flow field provided in the form of a sheet bonded at the rim of the insert and the interface thereof while being thermally bonded and for discharging generated water generated in the insert along the longitudinal direction at the widthwise edge.

An elastomeric cell frame for a fuel cell according to an embodiment of the present disclosure includes, as a cell frame constituting a unit cell of a fuel cell, an insert including a membrane electrode assembly having an anode formed on one surface of a polymer electrolyte membrane, and having a cathode formed on the other surface thereof, and a pair of gas diffusion layers disposed on both surfaces thereof; and an elastomeric frame disposed to surround the rim of the insert in the outer region of the insert, and formed with a discharge flow field provided in the form of a sheet bonded at the rim of the insert and the interface thereof while being thermally bonded and for discharging generated water generated in the insert along the longitudinal direction at the widthwise edge.

Provided is a fuel cell stack manufacturing method that can achieve a uniform pitch between fuel cells, that is, unit cells, and can increase the sealing properties between the unit cells. The fuel cell stack manufacturing method is a method for manufacturing a fuel cell stack including the lamination of a plurality of unit cells. This method includes a conveying step and a stacking step. The conveying step conveys the unit cell with its opposite ends held in a state where a pair of separators forming the unit cell vertically faces each other. The stacking step stacks in the vertical direction the plurality of unit cells with the gasket interposed therebetween. The upper and lower sides of the unit cells in the stacking step are inverted from those of the unit cells in the conveying step.

A separator for a fuel cell forms a stacked unit of a power generating cell stacked body. The separator is made up from a connected body of a first bipolar plate and a second bipolar plate that are stacked on each other, and is provided with positioning parts. The positioning parts are disposed at positions overlapping in the stacking direction with respect to each of the first bipolar plate and the second bipolar plate. A first positioning edge portion of the first bipolar plate and a second positioning edge portion of the second bipolar plate are at different positions from each other in a separator surface direction.

A unit cell includes a membrane electrode assembly, a resin frame member, a first separator, and a second separator. The membrane electrode assembly includes an electrolyte membrane, a first electrode, and a second electrode. A window section is formed in the resin frame member. An inner marginal portion of the window section enters between an outer marginal portion of the first electrode and an outer marginal portion of the electrolyte membrane. A ridge is provided on the second separator. The second separator is disposed adjacent to the second electrode. The ridge and the resin frame member are joined together through hot melt.

A fuel cell includes: an electrolyte membrane-electrode structure in which electrodes are provided on both surfaces of an electrolyte membrane and a frame member is joined to the outer peripheral portion of the electrolyte membrane; and a pair of separators for sandwiching the electrolyte membrane-electrode structure, wherein an overlapping portion of the outer peripheral portion of the electrode and the inner peripheral portion of the frame member is disposed in a flow field section in which flow field grooves for allowing a reactant gas to flow along the electrode surface of the electrolyte membrane-electrode structure are formed, and is disposed so as not to extend into buffers between the flow field section and passages.