A fuel cell including: a fuel cell stack; a pair of end plates holding the fuel cell stack by tightening from both ends; and a plurality of gas manifolds fixed to the fuel cell stack and end plates with the sealing members therebetween to supply fuel and oxidant to each of fuel gas flow paths and oxidant gas flow paths of the fuel cell stack, the fuel cell includes: a gas manifold fixing band including: hold plates installed in contact with a back of the gas manifold; a hold plate connecting part connecting the hold plates installed on the backs of adjacent gas manifolds; and a band-tightening part connecting and tightening both ends of a series of hold plates and the hold plate connecting part.

A fuel cell device has a mounting plate on which a fuel cell unit having a predefined number of fuel cells is arranged, the mounting plate and the fuel cell unit comprising media connections for guiding media, in particular for guiding a coolant and for guiding reactants, and electrical contact points for electrically connecting the fuel cell unit to the mounting plate. Further media connections and further electrical contact points are designed or arranged on the fuel cell unit in such a way that the fuel cell unit can be connected or is connected to a second fuel cell unit with a mechanical fluid connection for further guidance of the media and electrical connection for power uptake.

A fuel cell device has a mounting plate on which a fuel cell unit having a predefined number of fuel cells is arranged, the mounting plate and the fuel cell unit comprising media connections for guiding media, in particular for guiding a coolant and for guiding reactants, and electrical contact points for electrically connecting the fuel cell unit to the mounting plate. Further media connections and further electrical contact points are designed or arranged on the fuel cell unit in such a way that the fuel cell unit can be connected or is connected to a second fuel cell unit with a mechanical fluid connection for further guidance of the media and electrical connection for power uptake.

A fuel cell includes a cell stack including a plurality of unit cells stacked in a first direction, end plates respectively disposed at first and second end portions of the cell stack, each of the end plates including a core having first rigidity and a clad covering at least a portion of the core, the clad having second rigidity which is lower than the first rigidity, a heater plate provided with a heating element configured to generate heat in response to a driving power supply, the heater plate being disposed at at least one of positions between the end plates and the first and second end portions of the cell stack, and a connector accommodated in the core of each of the end plates and covered by the clad, the connector interconnecting the driving power supply and the heating element.

A fuel cell includes a cell stack including a plurality of unit cells stacked in a first direction, end plates respectively disposed at first and second end portions of the cell stack, each of the end plates including a core having first rigidity and a clad covering at least a portion of the core, the clad having second rigidity which is lower than the first rigidity, a heater plate provided with a heating element configured to generate heat in response to a driving power supply, the heater plate being disposed at at least one of positions between the end plates and the first and second end portions of the cell stack, and a connector accommodated in the core of each of the end plates and covered by the clad, the connector interconnecting the driving power supply and the heating element.

The present disclosure provides a battery module. The battery module includes a plurality of batteries that are stacked and two end plates disposed at two ends of the plurality of batteries in a stacking direction of the batteries. The battery module further includes a fixing strap, which includes a strap-shaped body and an elastic fixing part. The strap-shaped body surrounds the plurality of batteries and the end plates and defines a gap. The elastic fixing part is disposed in the gap and connected to the strap-shaped body. The elastic fixing part, together with the strap-shaped body, can provide an expansion space for the battery module with a certain restraint. In this way, the deformation of the battery module can be suppressed, and the battery module is protected from being damaged by a shear force of the strap-shaped body, thereby improving reliability of the battery performance.

A fuel cell assembly including a fuel cell stack having a first stack end and a second stack end, a first end plate located at the first stack end, and a second end plate located at the second stack end. The fuel cell stack being interposed between the first end plate and the second end plate. The fuel cell assembly including a compliant assembly extending from a first end to a second end located opposite the first end. The compliant assembly is configured to anchor together the fuel cell stack, the first end plate, and the second end plate. The compliant assembly include a rod extending from a first rod end to a second rod end. The compliant assembly also includes a connector body secured to the rod at or proximate the first rod end and an anchoring mechanism secured to the connector body.

A fuel cell assembly including a fuel cell stack having a first stack end and a second stack end, a first end plate located at the first stack end, and a second end plate located at the second stack end. The fuel cell stack being interposed between the first end plate and the second end plate. The fuel cell assembly including a compliant assembly extending from a first end to a second end located opposite the first end. The compliant assembly is configured to anchor together the fuel cell stack, the first end plate, and the second end plate. The compliant assembly include a rod extending from a first rod end to a second rod end. The compliant assembly also includes a connector body secured to the rod at or proximate the first rod end and an anchoring mechanism secured to the connector body.

An electrochemical hydrogen pump includes: at least one hydrogen pump unit including an electrolyte membrane, an anode, a cathode, an anode separator, and a cathode separator; an anode end plate disposed on the anode separator positioned in a first end in a stacking direction, the first end is one end and the second end is another end; a cathode end plate disposed on the cathode separator positioned in a second end in the stacking direction; a fixing member that prevents at least members from the cathode end plate to the cathode separator positioned in the second end from moving in the stacking direction; a first gas flow channel through which hydrogen generated in the cathode is supplied to a first space disposed between the cathode end plate and the cathode separator positioned in the second end; and a first pressure transmitting member disposed in the first space.

An electrochemical hydrogen pump includes: at least one hydrogen pump unit including an electrolyte membrane, an anode, a cathode, an anode separator, and a cathode separator; an anode end plate disposed on the anode separator positioned in a first end in a stacking direction, the first end is one end and the second end is another end; a cathode end plate disposed on the cathode separator positioned in a second end in the stacking direction; a fixing member that prevents at least members from the cathode end plate to the cathode separator positioned in the second end from moving in the stacking direction; a first gas flow channel through which hydrogen generated in the cathode is supplied to a first space disposed between the cathode end plate and the cathode separator positioned in the second end; and a first pressure transmitting member disposed in the first space.