This invention provides a laser welding method in which a state where the irradiation energy density becomes excessively high by a plurality of times of irradiation with laser is not caused and a defect, such as a hole, does not occur in a workpiece. In order to achieve the object, a laser welding method for welding a plurality of workpieces by irradiating the workpieces in a stacked state with a laser beam is characterized in that, when the laser beam is reciprocatingly emitted along a fixed welding line, the irradiation positions of a start end A and a termination end A″ of the irradiation are shifted away from each other so that the irradiation energy can be dispersed. Moreover, when the laser beam is emitted a plurality of times in the same direction along the fixed welding line, the irradiation positions of the start ends or/and the termination ends of the irradiation are shifted away from each other so that the irradiation energy can be dispersed.

This invention provides a laser welding method in which a state where the irradiation energy density becomes excessively high by a plurality of times of irradiation with laser is not caused and a defect, such as a hole, does not occur in a workpiece. In order to achieve the object, a laser welding method for welding a plurality of workpieces by irradiating the workpieces in a stacked state with a laser beam is characterized in that, when the laser beam is reciprocatingly emitted along a fixed welding line, the irradiation positions of a start end A and a termination end A″ of the irradiation are shifted away from each other so that the irradiation energy can be dispersed. Moreover, when the laser beam is emitted a plurality of times in the same direction along the fixed welding line, the irradiation positions of the start ends or/and the termination ends of the irradiation are shifted away from each other so that the irradiation energy can be dispersed.

A fuel cell stack includes: a first fuel cell and a second fuel cell, each of which has a structure in which a solid oxide electrolyte layer having oxygen ion conductivity is provided between two electrode layers; and an interconnector that is provided between the first fuel cell and the second fuel cell and has a separator made of a metal material, wherein the interconnector has a first metal porous part and a first gas passage on a first face of the separator on a side of the first fuel cell, wherein the interconnector has a second metal porous part and a second gas passage on a second face of the separator on a side of the second fuel cell.

A Solid Oxide Cell stack has an integrated interconnect and spacer, which is formed by bending a surplus part of the plate interconnect 180° to form a spacer part on top of the interconnect and connected to the interconnect at least by the bend.

A fuel cell separator includes a separator main body having a first surface and a second surface, and a first seal member disposed on the first surface. When a region on the first surface of the separator main body corresponding to an electrode member disposed on the second surface is defined as a power generation region, and a region on the first surface of the separator main body corresponding to an in-cell seal member is defined as a seal region, a displacement/vibration reducing member made of polymer is disposed at a part of the seal region. The displacement/vibration reducing member includes multiple protrusions and a coupling portion. When viewed in plan view, an axis line connecting the centers of the figures of the adjacent protrusions does not coincide with a center line passing through the widthwise center of the coupling portion. The coupling portion has a gate cut mark.

A fuel battery cell includes: a first separator, a first gas diffusion layer, a first catalyst layer, a polymer electrolyte membrane, a second catalyst layer, a second gas diffusion layer, and a second separator that are sequentially laminated along a laminating direction; a first gas flow path part that is provided between the first separator and the first gas diffusion layer; and a second gas flow path part that is provided between the first separator and the first gas diffusion layer and adjacent to the first gas flow path part in a direction intersecting the laminating direction, and has a flow path area larger than that of the first gas flow path part in a plan view seen along the laminating direction. The first gas diffusion layer includes a first low-elasticity part facing the first gas flow path part, and a first high-elasticity part facing the second gas flow path part and having a higher compressive modulus of elasticity than that of the first low-elasticity part in the laminating direction.

A fuel cell includes: a membrane electrode assembly (MEA); a first separator stacked on a first surface of the membrane electrode assembly; a second separator stacked on a second surface of the membrane electrode assembly; a first sealing member disposed on the first separator and configured to seal a space between the first separator and the membrane electrode assembly; a second sealing member disposed on the second separator and configured to seal a space between the second separator and the membrane electrode assembly; and a fastening part configured to fasten the first sealing member to the second sealing member.

An electrolyte membrane and method for generating the membrane provide a resistance as low as possible to minimize ohmic losses. The membrane has a low permeability for redox-active species. If redox-active species still cross the membrane, this transport is balanced during charge and discharge preventing a net vanadium flux and associated capacity fading. The membrane is mechanically robust, chemically stable in electrolyte solution, and low cost. A family of ion exchange membranes including a bilayer architecture achieves these requirements. The bilayer membrane includes two polymers, i) a polymer including N-heterocycles with electron lone pairs acting as proton acceptor sites and ii) a mechanically robust polymer acting as a support, which can be a dense cation exchange membrane or porous support layer. This bilayer architecture permits a very thin polymer film on a supporting polymer to minimize ohmic resistance and tune electrolyte transport properties of the membrane.

A cell includes a support substrate, electricity generation element parts that are arrayed at locations on a principal face of the support substrate and include a fuel electrode, a solid electrolyte, and an air electrode, and electrical connection parts that are each provided between adjacent electricity generation element parts and electrically connect a fuel electrode of one of the electricity generation element parts and an air electrode of another of the electricity generation element parts, wherein an electrical connection part bridges over the adjacent electricity generation element parts and includes air electrode collector parts, and the air electrode collector parts include a first site on an electricity generation element part on a side of a first end, a second site on the electricity generation element part other than the third end part, and a third site on a side of a second end.

A fuel cell separator member forming a power generation cell includes a first separator, and a load receiver member disposed in a manner to protrude outward from the first separator. Reinforcement ribs extending in a direction in which the load receiver member protrudes are provided in a part of an outer peripheral portion of the first separator, the part being adjacent to a joint portion.