Disclosed is an improved fuel cell apparatus. The fuel cell apparatus comprises at least one fuel cell, the fuel cell comprising two bipolar plates (200a 200b), one providing an anode side, and the other providing a cathode side, the fuel cell being configured to have a fuel inlet and a fuel outlet, and a membrane electrode assembly (422) disposed between the fuel inlets (201) and fuel outlets (203) of the bipolar plates. The at least one fuel cell is retained by a housing, the housing comprising a first outer plate and a second outer plate, each located on an opposite face of the at least one fuel cell. The housing further comprises a cooling element support which is adapted to support one or more fans that are adapted to provide an air flow toward the at least one fuel cell.

Disclosed is an improved fuel cell apparatus. The fuel cell apparatus comprises at least one fuel cell, the fuel cell comprising two bipolar plates (200a 200b), one providing an anode side, and the other providing a cathode side, the fuel cell being configured to have a fuel inlet and a fuel outlet, and a membrane electrode assembly (422) disposed between the fuel inlets (201) and fuel outlets (203) of the bipolar plates. The at least one fuel cell is retained by a housing, the housing comprising a first outer plate and a second outer plate, each located on an opposite face of the at least one fuel cell. The housing further comprises a cooling element support which is adapted to support one or more fans that are adapted to provide an air flow toward the at least one fuel cell.

A device for producing and/or storing electrical energy (2), characterized in that the device comprises: an anode (4), a cathode (6), a separator (8) allowing for the transfer of at least one compound capable of triggering and/or enabling a production and/or storage of electrical energy (8), arranged between the anode (4) and the cathode (6), and at least one breakable, pierceable, and/or deformable reservoir (10) made of a compound capable of triggering and/or enabling a production and/or a storage of electrical energy, said reservoir (10) having means for bringing said compound and said separator (8) into contact with each other; said means for bringing said compound and said separator (8) into contact with each other being, in particular, means for transferring a liquid.

A device for producing and/or storing electrical energy (2), characterized in that the device comprises: an anode (4), a cathode (6), a separator (8) allowing for the transfer of at least one compound capable of triggering and/or enabling a production and/or storage of electrical energy (8), arranged between the anode (4) and the cathode (6), and at least one breakable, pierceable, and/or deformable reservoir (10) made of a compound capable of triggering and/or enabling a production and/or a storage of electrical energy, said reservoir (10) having means for bringing said compound and said separator (8) into contact with each other; said means for bringing said compound and said separator (8) into contact with each other being, in particular, means for transferring a liquid.

The bipolar separator is formed by the superimposition of two distribution plates and two cooling plates, the two cooling plates being arranged between the two distribution plates, each distribution plate having an outer face and an inner face, the outer face of each distribution plate being provided with distribution channels for the flow of a reactive fluid, the cooling plates defining internal conduits for the circulation of a cooling fluid.

A separator plate arrangement for an electrochemical system, comprising a first metal sheet and a second metal sheet. The first metal sheet has a first circumferential sealing structure for sealing off an electrochemically active region, a first cutout arranged outside of the first circumferential sealing structure, and a first embossed structure arranged outside of the first circumferential sealing structure. The second metal sheet has a second circumferential sealing structure for sealing off an electrochemically active region, a second cutout arranged outside of the second circumferential sealing structure, and a second embossed structure arranged outside of the second circumferential sealing structure.

A method for producing bipolar plates for fuel cells, one metal strip or two metal strips is/are guided through a second or third device. The second device is designed to carry out fine cleaning and/or nitriding of the metal strip, and the third device carries out surface coating on one side of a surface with a metal layer that improves adhesion. Applying a carbon layer in a fourth device. The metal strips are then shaped, during which process channels are formed. The shaped metal strips are moved and positioned such that surface regions come into contact with one another. Joining is performed with a laser beam, which is directed into a gap between the shaped metal strips moved towards one another. The individual steps in the devices, like shaping and joining, are carried out in a continuous process.

A method for producing bipolar plates for fuel cells, one metal strip or two metal strips is/are guided through a second or third device. The second device is designed to carry out fine cleaning and/or nitriding of the metal strip, and the third device carries out surface coating on one side of a surface with a metal layer that improves adhesion. Applying a carbon layer in a fourth device. The metal strips are then shaped, during which process channels are formed. The shaped metal strips are moved and positioned such that surface regions come into contact with one another. Joining is performed with a laser beam, which is directed into a gap between the shaped metal strips moved towards one another. The individual steps in the devices, like shaping and joining, are carried out in a continuous process.

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.

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.