A separator plate for an electrochemical system may have at least one passage opening for forming a media channel for feeding or discharging media. The system may also have at least one bead arrangement arranged around the at least one passage opening, for the purpose of sealing the passage opening. At least one of the flanks of the bead arrangement may have at least one opening for conducting a medium through the bead flank. The system may also have at least one guide channel that is connected, on an exterior of the bead arrangement, to the openings in the bead flank and is fluidically connected to a bead interior via the opening in the bead flank. The guide channel is designed such that a guide channel width, determined parallel to the flat surface plane of the separator plate, increases at least in some sections in the direction of the bead arrangement.

A separator plate for an electrochemical system may have at least one passage opening for forming a media channel for feeding or discharging media. The system may also have at least one bead arrangement arranged around the at least one passage opening, for the purpose of sealing the passage opening. At least one of the flanks of the bead arrangement may have at least one opening for conducting a medium through the bead flank. The system may also have at least one guide channel that is connected, on an exterior of the bead arrangement, to the openings in the bead flank and is fluidically connected to a bead interior via the opening in the bead flank. The guide channel is designed such that a guide channel width, determined parallel to the flat surface plane of the separator plate, increases at least in some sections in the direction of the bead arrangement.

A fuel cell stack includes: a membrane electrode assembly; and first and second separators joined to each other, wherein first and third fluid groove portions face each other in a stacking direction in which the membrane electrode assembly and the first and second separators are stacked, second and fourth fluid groove portions face each other in the stacking direction, and first and second coolant groove portions face each other in the stacking direction and define a common coolant flow path.

A fuel cell includes a power-generation channel provided on a surface of a cathode-side separator which faces a MEA and a cooling channel provided on a surface of the cathode-side separator opposite to the MEA. Air flows through the power-generation channel and the cooling channel. The cooling channel is separated from the power-generation channel by a side wall. The cross-sectional area of the power-generation channel on the air outlet side is smaller than that of the power-generation channel at a position upstream of the air outlet side, and the cross-sectional area of the cooling channel on the air outlet side is larger than that of the cooling channel at a position upstream of the air outlet side. A through-hole is provided in a side wall that separates the power-generation channel from the cooling channel.

A fuel cell includes a power-generation channel provided on a surface of a cathode-side separator which faces a MEA and a cooling channel provided on a surface of the cathode-side separator opposite to the MEA. Air flows through the power-generation channel and the cooling channel. The cooling channel is separated from the power-generation channel by a side wall. The cross-sectional area of the power-generation channel on the air outlet side is smaller than that of the power-generation channel at a position upstream of the air outlet side, and the cross-sectional area of the cooling channel on the air outlet side is larger than that of the cooling channel at a position upstream of the air outlet side. A through-hole is provided in a side wall that separates the power-generation channel from the cooling channel.

The present invention provides a fuel cell and a cell unit thereof, and an electric stack structure. The fuel cell has an internal common channel structure constituted by openings in various shapes two-dimensionally arranged in the plane of the cell unit. The two-dimensional arrangement of the openings has periodicity or periodicity of fluctuation to a certain extent, and the fuel fluid, cooling medium, and oxidation fluid are evenly provided and discharged to the fuel cell in the in-plane direction and stack direction of the cell unit. Provision of a sealing material in the opening in each layer of the cell unit guides the fuel fluid, the cooling medium, and the oxidation fluid to properly flow into the corresponding layer.

To provide a space-saving bipolar plate for a fuel cell comprising an anode plate and a cathode plate, anode gas channels and cathode gas channels lead from main gas ports on opposite sides into an active area and are distributed across the width of said area such that they are subsequently diverted towards an opposite distribution area, and the coolant channels branch in the distribution area and, after branching, are diverted towards the anode gas channels and towards the cathode gas channels and, in each region of overlap with the anode gas channels and the cathode gas channels, are diverted collectively such that the coolant channels lead, together with the anode gas channels and the cathode gas channels, into the active area with no overlap and alternatingly with said anode gas channels and cathode gas channels.

To provide a space-saving bipolar plate for a fuel cell comprising an anode plate and a cathode plate, anode gas channels and cathode gas channels lead from main gas ports on opposite sides into an active area and are distributed across the width of said area such that they are subsequently diverted towards an opposite distribution area, and the coolant channels branch in the distribution area and, after branching, are diverted towards the anode gas channels and towards the cathode gas channels and, in each region of overlap with the anode gas channels and the cathode gas channels, are diverted collectively such that the coolant channels lead, together with the anode gas channels and the cathode gas channels, into the active area with no overlap and alternatingly with said anode gas channels and cathode gas channels.

The present invention relates to a separation plate, a manufacturing method therefor, and a fuel cell stack comprising the same, and according to one aspect of the present invention, provided is a separation plate having: a first surface and a second surface in a direction opposite to that of the first surface; a plurality of channel elements protruding from the second surface toward the first surface, wherein each of the channel elements is arranged to have an inlet port and an outlet port along the flowing direction of a fluid flowing on the first surface; and a rib having a height varying along the circumferential direction of a virtual axis connecting the inlet port and the outlet port, wherein at least a partial region of an outer surface of the rib is formed into a cycloid curved surface along the circumferential direction of the virtual axis.

The present invention relates to a separation plate, a manufacturing method therefor, and a fuel cell stack comprising the same, and according to one aspect of the present invention, provided is a separation plate having: a first surface and a second surface in a direction opposite to that of the first surface; a plurality of channel elements protruding from the second surface toward the first surface, wherein each of the channel elements is arranged to have an inlet port and an outlet port along the flowing direction of a fluid flowing on the first surface; and a rib having a height varying along the circumferential direction of a virtual axis connecting the inlet port and the outlet port, wherein at least a partial region of an outer surface of the rib is formed into a cycloid curved surface along the circumferential direction of the virtual axis.