Abstract: A metal separator is stacked on each of both surfaces of a membrane electrode assembly to form a fuel cell. A method of producing the metal separator includes a metal plate processing step of producing a metal plate including a fluid passage and a fluid flow field, and a rubber adding step of adhering a plurality of rubber extension parts extending from the fluid passage toward the fluid flow field, to the metal plate. In the rubber adding step, a primer is coated on the metal plate in an island pattern, and the metal plate and the rubber extension parts are adhered together through the primer in a dot pattern.

Abstract: Each of a fuel cell and a fuel cell stack includes an anode discharge passage connected to one end of a fuel gas flow field in the horizontal direction and configured to discharge a fuel gas in a stacking direction in which a membrane electrode assembly and separators are stacked, and a cathode discharge passage connected to another end of an oxygen-containing gas flow field in the horizontal direction and configured to discharge an oxygen-containing gas in the stacking direction. A bottom portion of a lowermost cathode discharge passage is provided below a bottom portion of a lowermost anode discharge passage.

Abstract: A wiring substrate includes an insulating layer, a conductor layer formed on the insulating layer and including a conductor pad, and a solder resist layer formed on the insulating layer such that the solder resist layer has an opening entirely exposing an upper surface and a side surface of the conductor pad. The conductor layer is formed such that the conductor pad has a pad body extending along a surface of the insulating layer, and a protective layer covering an upper surface and a side surface of the pad body and including material different from material of the pad body, and the pad body of the conductor pad has a notch part formed at a peripheral edge portion of the pad body such that the notch part separates a lower surface of the pad body and the surface of the insulating layer and is filled with the protective layer.

Abstract: A first separator member forming a power generation cell, which is a fuel cell, includes a first separator body. A first support bead, which is formed to be lower in height than a first seal bead and restricts the inclination of the first seal bead, is provided outside a first seal in the first separator body. The width of the first support bead varies depending on the position of the first support bead in the direction in which the first support bead extends.

Abstract: A coolant flow field of a fuel cell stack includes a power-generation-portion-cooling flow path including a portion overlapping a power generation section of a membrane electrode assembly, a bypass flow path provided on outer peripheries of separators, a main supply flow path extending from a coolant supply passage through the bypass flow path and communicating with the power-generation-portion-cooling flow path, and a bubble release flow path extending from an upper portion of the coolant supply passage in the gravity direction toward the bypass flow path and communicating with the bypass flow path, wherein the bubble release flow path extends upward in the gravity direction above the coolant supply passage.

Abstract: A substrate processing system includes a carry-in/out unit in which a cassette accommodating therein multiple substrates is carried in and out; a batch processing unit configured to process a lot including the multiple substrates at once; a single-wafer processing unit configured to process the substrates one by one; a first interface unit configured to distribute the substrates to the single-wafer processing unit or the batch processing unit; and a second interface unit configured to transfer the substrates between the batch processing unit and the single-wafer processing unit. The first interface unit includes a first placement unit configured to place therein the substrates before and after being processed by the single-wafer processing unit; a second placement unit configured to place therein the substrates before being processed by the batch processing unit; and a transfer device configured to transfer the substrates to the first placement unit and the second placement unit.

Abstract: A wiring substrate includes an insulating layer, a conductor layer formed on the insulating layer and including a conductor pad, and a solder resist layer formed on the insulating layer such that the solder resist layer has an opening entirely exposing an upper surface and a side surface of the conductor pad. The conductor layer is formed such that the conductor pad has a pad body extending along a surface of the insulating layer, and a protective layer covering an upper surface and a side surface of the pad body and including material different from material of the pad body, and the pad body of the conductor pad has a notch part formed at a peripheral edge portion of the pad body such that the notch part separates a lower surface of the pad body and the surface of the insulating layer and is filled with the protective layer.

Abstract: A substrate processing apparatus 1 includes a controller 61 configured to perform a first recipe and a second recipe in parallel. Each of the first recipe and the second recipe includes a first transfer processing of transferring a substrate from a transit unit 14 to a liquid processing unit 17, a liquid processing, a second transfer processing of transferring the substrate from the liquid processing unit 17 to a drying unit 18 and a drying processing. The controller 61 determines, while the first recipe on a first substrate in substrates is being performed, when the second recipe on a second substrate in the substrates is started, a start timing of the first transfer processing of the second substrate such that a time period of the second transfer processing of the first substrate does not overlap with a time period of the second transfer processing of the second substrate.

Abstract: A coolant flow field of a fuel cell stack includes a power-generation-portion-cooling flow path including a portion overlapping a power generation section of a membrane electrode assembly, a bypass flow path provided on outer peripheries of separators, a main supply flow path extending from a coolant supply passage through the bypass flow path and communicating with the power-generation-portion-cooling flow path, and a bubble release flow path extending from an upper portion of the coolant supply passage in the gravity direction toward the bypass flow path and communicating with the bypass flow path, wherein the bubble release flow path extends upward in the gravity direction above the coolant supply passage.

Abstract: Each of a fuel cell and a fuel cell stack includes an anode discharge passage connected to one end of a fuel gas flow field in the horizontal direction and configured to discharge a fuel gas in a stacking direction in which a membrane electrode assembly and separators are stacked, and a cathode discharge passage connected to another end of an oxygen-containing gas flow field in the horizontal direction and configured to discharge an oxygen-containing gas in the stacking direction. A bottom portion of a lowermost cathode discharge passage is provided below a bottom portion of a lowermost anode discharge passage.

Abstract: A bipolar plate is provided that prevents pressure leaks from occurring at a seal bead. A fuel battery gasket is provided. The gasket is structured to include a pair of metal-made bipolar plates, seal beads, and a tunnel. The bipolar plates are interposed between a plurality of reaction electrode portions. The bipolar plates are fastened together with the reaction electrode portions and thereby joined to each other. The seal beads are provided at one or both of the bipolar plates by being patterned in full-bead forms. The tunnel is bridged between the adjacent seal beads and allows their insides to communicate with each other. When a height of the seal bead is H1 and a height of the tunnel is H2, H1/H2 is set to be equal to or larger than 1.6.

Abstract: A fuel cell separator member of a fuel cell stack includes a metal separator on which a seal bead is formed, and a pressure receiving member provided on a surface of the metal separator, separately from the metal separator. The pressure receiving member is provided along a seal bead, and the height of the pressure receiving member is lower than the height of the seal bead in the state where the tightening load is applied and no impact load is applied.

Abstract: A first separator member forming a power generation cell, which is a fuel cell, includes a first separator body. A first support bead, which is formed to be lower in height than a first seal bead and restricts the inclination of the first seal bead, is provided outside a first seal in the first separator body. The width of the first support bead varies depending on the position of the first support bead in the direction in which the first support bead extends.

Abstract: A substrate processing apparatus includes first processors, second processors, a transfer module and a controller. Each of the first processors is configured to perform a first processing on a substrate. Each of the second processors is configured to perform a second processing on the substrate on which the first processing is performed. The transfer module is configured to transfer the substrate to the first processors and the second processors. The controller is configured to control the first processors, the second processors and the transfer module. The controller controls a start timing for a first transfer processing of transferring the substrates to the first processor such that a timing of a second transfer processing of transferring the substrate having a liquid film formed thereon to the second processor from the first processor and a timing when another substrate is transferred by the transfer module are not overlapped with each other.

Abstract: A metal separator is stacked on each of both surfaces of a membrane electrode assembly to form a fuel cell. A method of producing the metal separator includes a metal plate processing step of producing a metal plate including a fluid passage and a fluid flow field, and a rubber adding step of adhering a plurality of rubber extension parts extending from the fluid passage toward the fluid flow field, to the metal plate. In the rubber adding step, a primer is coated on the metal plate in an island pattern, and the metal plate and the rubber extension parts are adhered together through the primer in a dot pattern.

Abstract: A fuel cell separator member of a fuel cell stack includes a metal separator on which a seal bead is formed, and a pressure receiving member provided on a surface of the metal separator, separately from the metal separator. The pressure receiving member is provided along a seal bead, and the height of the pressure receiving member is lower than the height of the seal bead in the state where the tightening load is applied and no impact load is applied.

Abstract: Bead seal structure includes an outer bead (bead seal) for preventing leakage of fluid, and a first bypass stop protrusion (intersecting element) which intersects with the outer bead. The first bypass stop protrusion includes a root as a rising start point from a base plate and side walls which rise from the base plate. The radius of curvature of connection parts of the roots connected to the outer bead is larger than the radius of curvature of connection parts of the side walls connected to the outer bead.

Abstract: A method of manufacturing a plate with an insulating frame by using a metal mold. The plate includes an outer edge portion having a concavo-concave shape, and the metal mold includes a plurality of gate portions for injecting a molding material that forms the frame. The gate portions of the metal mold are at locations that correspond to the concave portions of the metal plate such that when the molding material is injected into the metal mold, an injection pressure of the molding material that can deform the metal plate will not deform the metal plate to an extent that deteriorates insulation resistance that is provided by the frame.

Abstract: A separator member of a fuel cell stack includes a load receiver in a form of a plate. The load receiver is joined to a first separator in a manner that the load receiver protrudes outward from an outer peripheral portion of the first separator. The load receiver is formed asymmetrically about a central line passing through the center of the load receiver in the width direction and extending in the protruding direction of the load receiver.

Abstract: A joint line includes a passage joint line, a first outer joint line provided in outer peripheral portions of a first metal separator and a second metal separator, and a second outer joint line provided in the outer peripheral portions of the first metal separator and the second metal separator around the first outer joint line.