Abstract: The invention relates to a fuel cell having an anode/cathode stack, which comprises at least one active surface layer, which is designed having a first channel structure having a plurality of first channels for conducting a first fluid in a first direction over the surface layer, which is designed having a second channel structure having a plurality of second channels for conducting a second fluid in a second direction over the surface layer, wherein the second direction extends substantially perpendicularly to the first direction, which is designed having a first feeding structure for feeding the first fluid into the plurality of first channels, and which is designed having a second feeding structure for feeding the second fluid into the plurality of second channels.

Abstract: A method for repairing a fuel cell stack having a plurality of individual cells involves the steps of: a) identifying at least one degraded individual cell in the fuel cell stack; and b) deactivating the at least one degraded individual cell.

Abstract: A fuel cell having an ion-selective separator, a gas diffusion layer and a separator plate, is provided. The separator plate forms, together with the gas diffusion layer, at least one gas-conducting flow field. At least one convergent duct section and at least one divergent duct section are formed in the flow field, wherein the convergent duct section lies adjacent to the divergent duct section. A barrier is provided between the convergent duct section and the divergent duct section such that the gas flows at least partially through the gas diffusion layer in order to pass directly from the convergent duct section into the divergent duct section. At least one additional convergent duct section, at least one additional divergent duct section and at least one additional barrier are provided downstream of the convergent duct section and/or downstream of the divergent duct section.

Abstract: An exhaust air guide of a fuel cell stack is provided, in particular in a motor vehicle, with a cooling device which belongs to the functional environment of the fuel cell stack and is in the form of a cooler structure through which ambient air flows. At least some of the exhaust air of the fuel cell stack is guided into the cooler structure or behind the cooler structure, as viewed in the direction of flow of the ambient air through the cooler structure, to such an extent that, at the cooler structure, the exhaust air flow brings about an increase in the mass flow of the ambient air through the cooler structure in accordance with the jet pump principle or, at the cooler structure, the exhaust air flow, in accordance with the jet pump principle, brings about a pressure difference conveying at least a portion of the ambient air through the cooler structure.

Abstract: An operating method is provided for a fuel cell system with a radiator structure which is flowed through by ambient air and a fuel cell stack, at least part of the outgoing air flow of the fuel cell stack can be guided onto the radiator structure such that, at the radiator structure, the guided outgoing air flow causes an increase in mass flow of the ambient air through the radiator structure according to the jet pump principle. At least part of the outgoing air flow of the fuel cell stack can be guided through a gas expansion machine. The division of energy which is contained in the outgoing air flow and can be recovered in the gas expansion machine and/or at the radiator structure according to the jet pump principle is changed by an electronic control unit in a manner which is adapted to boundary conditions.

Abstract: In a motor vehicle having a fuel cell, an air compressor provides input air under pressure at the fuel cell and an electric drive motor for driving the motor vehicle, which drive motor can be supplied with electric current by the fuel cell for that purpose, wherein the air compressor is driven by the drive motor.

Abstract: A housing is provided for a fuel cell stack. The housing includes two end plates, two opposite side walls, a lateral connecting wall, and at least one media exchange element. The two end plates are arranged at the two ends of the fuel cell stack. The two opposite side walls connect the end plates to each other. The lateral connecting wall connects the opposite side walls to each other. The at least one media exchange element has media connections. At least the two end plates are each designed as an extruded supporting structure. The media connections are not fed across the end plates.

Abstract: A bipolar plate, has a base area and raised structures provided thereon. The raised structures each have a first region and a second region. The first region is designed to penetrate into a gas diffusion layer that is to be brought into contact with the bipolar plate and to increase the contact area between the bipolar plate and the gas diffusion layer. The second region is between the base area of the bipolar plate and the first region of the raised structures. The first region and/or the second region is/are of such a form and/or arrangement that the base area of the bipolar plate and the gas diffusion layer are kept apart.

Abstract: An operating method is provided for a fuel cell system with a radiator structure which is flowed through by ambient air and a fuel cell stack, at least part of the outgoing air flow of the fuel cell stack can be guided onto the radiator structure such that, at the radiator structure, the guided outgoing air flow causes an increase in mass flow of the ambient air through the radiator structure according to the jet pump principle. At least part of the outgoing air flow of the fuel cell stack can be guided through a gas expansion machine. The division of energy which is contained in the outgoing air flow and can be recovered in the gas expansion machine and/or at the radiator structure according to the jet pump principle is changed by an electronic control unit in a manner which is adapted to boundary conditions.

Abstract: A fuel cell system is provided having a plurality of fuel cells combined to form a fuel cell stack. The fuel cell system is characterized in that at least one fuel cell is a redox flow fuel cell having an electrode assembly, which electrode assembly has a proton-permeable separator, which separator is arranged between an anode region and a cathode region. The redox flow fuel cell has a regenerator spatially separated from the electrode assembly, and a water-forming reaction of the redox flow fuel cell occurs in the regenerator. The redox flow fuel cell also has at least one oxidation-fluid delivery unit for feeding oxidation fluid into the regenerator in order to perform the water-forming reaction in the regenerator of the redox flow fuel cell. The redox flow fuel cell also has a pumping circuit, comprising a pumping device and a pumping line, for transporting an electrochemical storage system through the cathode region or the anode region of the redox flow fuel cell and through the regenerator.

Abstract: A method is provided for producing a fuel cell, which method includes the arrangement of in each case one gas diffusion layer with in each case one bipolar plate on a respective side of a membrane electrode arrangement which comprises an anode, a cathode and an electrolyte membrane arranged between the anode and the cathode. The gas diffusion layers are set back in relation to the bipolar plates and the membrane electrode arrangement. The gas diffusion layers have in each case at least one reaction fluid supply region and in each case at least one reaction fluid discharge region and in each case at least one reaction fluid sealing region. The method is characterized by injecting a sealing material into at least one reaction fluid sealing region of at least one gas diffusion layer such that the gas diffusion layer is sealed off to the outside.

Abstract: An exhaust air guide of a fuel cell stack is provided, in particular in a motor vehicle, with a cooling device which belongs to the functional environment of the fuel cell stack and is in the form of a cooler structure through which ambient air flows. At least some of the exhaust air of the fuel cell stack is guided into the cooler structure or behind the cooler structure, as viewed in the direction of flow of the ambient air through the cooler structure, to such an extent that, at the cooler structure, the exhaust air flow brings about an increase in the mass flow of the ambient air through the cooler structure in accordance with the jet pump principle or, at the cooler structure, the exhaust air flow, in accordance with the jet pump principle, brings about a pressure difference conveying at least a portion of the ambient air through the cooler structure.

Abstract: A fuel cell system is provided having multiple individual fuel cells which are combined to form a fuel cell stack, and having two current collectors which adjoin the two end-side individual fuel cells. The current collectors are each adjoined directly, or with the interposition of an isolation plate, by an end plate. A heat accumulator is provided at least on one of the current collectors so as to adjoin that side of the latter which faces away from the individual fuel cells. The heat accumulator may be arranged in a recess of the end plate, or of an optionally provided isolation plate, and a compensation reservoir for a change in volume of the heat accumulator may be provided.

Abstract: A fuel cell system has a plurality of individual fuel cells which are combined into a stack, where each of the individual fuel cells has a substantially planar membrane-electrode unit, two gas diffusion layers in the form of a fiber structure and of a bipolar plate, which establishes the electrical connection to the adjacent individual fuel cell that is located above or below. The gas diffusion layers adjoin the larger surfaces of the membrane electrode unit, which are located opposite of one another, and the bipolar plate comprises an active region surrounded by an edge region. In addition, the bipolar plates in the active region have a completely flat design so that the gas-carrying region is formed exclusively by the gas diffusion layers, what amounts to at least 60% of the height of an individual fuel cell.

Abstract: In a motor vehicle having a fuel cell, an air compressor provides input air under pressure at the fuel cell and an electric drive motor for driving the motor vehicle, which drive motor can be supplied with electric current by the fuel cell for that purpose, wherein the air compressor is driven by the drive motor.

Abstract: The invention relates to a fuel cell having an anode/cathode stack, which comprises at least one active surface layer, which is designed having a first channel structure having a plurality of first channels for conducting a first fluid in a first direction over the surface layer, which is designed having a second channel structure having a plurality of second channels for conducting a second fluid in a second direction over the surface layer, wherein the second direction extends substantially perpendicularly to the first direction, which is designed having a first feeding structure for feeding the first fluid into the plurality of first channels, and which is designed having a second feeding structure for feeding the second fluid into the plurality of second channels.

Abstract: A fuel cell arrangement, in particular for a motor vehicle, includes a tank for storing a carrier fluid mixed with hydrogen, a separating device for separating hydrogen from the carrier fluid, a fuel cell for generating electrical energy from the hydrogen, and a heating arrangement for heating the carrier fluid mixed with hydrogen. The heating arrangement includes a first heat exchanger for heating the carrier fluid by way of a carrier fluid return line, and/or a second heat exchanger for heating the carrier fluid by way of the waste heat of the fuel cell, and/or a third heat exchanger for heating the carrier fluid by way of a compressed intake air.

Abstract: A fuel cell having an anode-cathode stack includes at least one active surface layer formed by a first channel structure with a first and at least one second channel for conducting a first fluid over the at least one active surface layer of the anode-cathode stack. A first distributor structure for distributing the first fluid into the first and the at least one second channel of the channel structure is provided. The first distributor structure is configured with a first surface region assigned to the first channel and with a second surface region assigned to the second channel. The two surface regions are configured with a flow resistance of differing magnitude for the first fluid distributed in the first distributor structure.

Abstract: An exhaust-air guide of a fuel cell stack having a cooling structure, in particular in a motor vehicle, is provided. The cooler structure belongs to the functional environment of the fuel cell stack and is in form through which ambient air flows. The exhaust air of the fuel cell stack is guided to a point upstream of the cooler structure such that the exhaust air flows through the cooler structure in a throughflow direction and, in so doing, entrains ambient air in accordance with the jet pump principle. The exhaust air of the fuel cell stack may be cooled before being guided to the cooler structure. The exhaust air of the fuel cell stack is guided to a point upstream of the cooler structure in multiple pipes that are oriented at least approximately parallel to the inflow surface of the cooler structure, from which pipes the exhaust air emerges via outlet openings in the pipe wall. The outlet openings are situated at a suitable angle with respect to the throughflow direction.

Abstract: A method for the production of protection devices is provided. The method includes the step of providing a tile package. The provision of the tile package includes the steps of: laminating at least one board of a tile material onto a polymer foil; scoring the board on the side which is opposite to the polymer foil; and fracturing the board along the scoring lines for achieving a plurality of tiles which are fixed on the polymer foil.