A method for producing a bipolar plate for a fuel cell having a membrane electrode assembly comprises providing a first fuel cell half-plate, which has a circumferential plate edge which has a first media channel offset inwardly from the plate edge and also a first flow field, providing a second fuel cell half-plate, which has a plate edge corresponding to the plate edge of the first fuel cell half-plate, and which has a second media channel offset inwardly from its plate edge and also a second flow field, the second media channel being aligned with the first media channel when the two fuel cell half-plates are stacked one above the other in perfect alignment, and joining the first fuel cell half-plate to the second fuel cell half-plate along a media-channel joint line framing the media channels, wherein a joint-line-free sealing region of the fuel cell half-plates borders the plate edges, on which a seal is fixed or is to be fixed, and the first fuel cell half-plate is joined to the second fuel cell half-plate along an additional frame joint line adjoining the media channel joint line or overlapping same, at least some sections of said additional frame joint line being offset along the plate edges in relation to the sealing region.

A method for an assemble system that assembles insulation plates and mounting bars to a stack, includes moving the stack pressed by a stack pressing device to an outside thereof; attaching, a insulation plate attaching device, the insulation plates to the stack; attaching, by a mounting bar attaching device, the mounting bars that is configured to fix the insulation plates to the stack; and assembling, by a bolt assembling device, bolts configured to fix the mounting bars to the stack.

A method for an assemble system that assembles insulation plates and mounting bars to a stack, includes moving the stack pressed by a stack pressing device to an outside thereof; attaching, a insulation plate attaching device, the insulation plates to the stack; attaching, by a mounting bar attaching device, the mounting bars that is configured to fix the insulation plates to the stack; and assembling, by a bolt assembling device, bolts configured to fix the mounting bars to the stack.

The invention relates to a stack of electrochemical cells (10A, 10B), divided up into at least two groups (A, B), each cell comprising a distribution circuit for a reactive species, and each group of cells comprising a separate supply collector (2A; 2B). At least one cell (10B) comprises a homogenization compartment (60B) comprising: a plurality of longitudinal conduits (61B) designed to receive the flow of the reactive species coming from the supply collector (2B) of the corresponding group and to distribute it over the inlet (51B) of the distribution circuit for the cell; and, a transverse conduit (62B) for homogenization connecting the longitudinal conduits (61B) to one another in a fluid sense.

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.

A bipolar plate for an electrochemical cell, includes a flow space arranged between a first and a second plate element and has a flow inlet and a flow outlet for a coolant flowing through the flow space. Each plate element has a contact plane for contacting the other plate element and, between the flow inlet and the flow outlet, a plurality of elevations protrude from the contact plane and face away from the other plate element. The elevations have openings facing the contact plane. First flow channels are formed through the openings in the elevations by the elevations of the two plate elements being offset from one another. Each elevation at least partially overlaps at least one elevation of the other plate element. A direction-dependent flow resistance is set in the first flow channels of the bipolar plate.

The embodiments herein disclose a system (1000) for managing electrical connections with electrodes in a metal-air fuel cell. The system (1000) includes a cell frame (101) and one or more anode array (102). The one or more anode array (102) is detachably provided with the cell frame (101). The one or more anode array (102) comprises one or more anode. One or more air cathode (103) is provided with the cell frame (101). One or more connector (105) connects the one or more air cathode (103) and the one or more anode array (102). A snap mechanism (106) is used for locking and unlocking the one or more anode array (102) to the cell frame (101).

The embodiments herein disclose a system (1000) for managing electrical connections with electrodes in a metal-air fuel cell. The system (1000) includes a cell frame (101) and one or more anode array (102). The one or more anode array (102) is detachably provided with the cell frame (101). The one or more anode array (102) comprises one or more anode. One or more air cathode (103) is provided with the cell frame (101). One or more connector (105) connects the one or more air cathode (103) and the one or more anode array (102). A snap mechanism (106) is used for locking and unlocking the one or more anode array (102) to the cell frame (101).

A manufacturing method includes a cleaning step of irradiating by laser light a joining site of a first separator to which a second separator is to be joined, without joining the first separator and the second separator. In the cleaning step, at least a part of a joining site is irradiated by the laser light such that a plurality of irradiation marks created by the laser light make up a separated irradiation mark pattern in which the irradiation marks are disposed separated from each other.

An inventive through transmission connecting device for connecting a first component made of a light absorbing material to a second component made of a light transmissive material by means of a light transmission bonding technology. The connecting device includes a first tool mounted to a first support retaining the first component and a second tool mounted to a second support retaining the second component. The first tool and the second tool are movable with respect to each other and the first tool is at least partly made of or includes a layer of a thermal isolator having a high thermal resistance.