A fuel cell system includes a stack of unit cells generating power using reaction gasses, an end plate stacked on an end face of the stack, a circulation passage for fuel off-gas, and an ejector including an inflow port for fuel gas, a suction port sucking fuel off-gas in from the circulation passage, an ejection port ejecting fuel gas and fuel off-gas, and a diffuser diffusing fuel gas and fuel off-gas toward the ejection port, the stack including a manifold through which fuel gas and fuel off-gas flow, the end plate having a recess accommodating the ejector, and a continuous hole between the ejection port and the manifold, the ejector being in contact with an inner face of the recess such that a flow direction of fuel gas and fuel off-gas in the diffuser is along a plate surface of the end plate and the suction port is exposed.

A fuel cell system includes a stack of unit cells generating power using reaction gasses, an end plate stacked on an end face of the stack, a circulation passage for fuel off-gas, and an ejector including an inflow port for fuel gas, a suction port sucking fuel off-gas in from the circulation passage, an ejection port ejecting fuel gas and fuel off-gas, and a diffuser diffusing fuel gas and fuel off-gas toward the ejection port, the stack including a manifold through which fuel gas and fuel off-gas flow, the end plate having a recess accommodating the ejector, and a continuous hole between the ejection port and the manifold, the ejector being in contact with an inner face of the recess such that a flow direction of fuel gas and fuel off-gas in the diffuser is along a plate surface of the end plate and the suction port is exposed.

A fuel cell stack includes a cell stack body and a terminal plate and an insulator disposed at an end of the cell stack body in a stacking direction. The cell stack body includes a plurality of stacked power generation cells. Each of the power generation cells includes a membrane electrode assembly and a separator. The terminal plate is disposed between the cell stack body and the insulator. Elastic structure which elastically presses the terminal plate toward the cell stack body is provided between the insulator and the terminal plate.

A fuel cell stack includes a cell stack body and a terminal plate and an insulator disposed at an end of the cell stack body in a stacking direction. The cell stack body includes a plurality of stacked power generation cells. Each of the power generation cells includes a membrane electrode assembly and a separator. The terminal plate is disposed between the cell stack body and the insulator. Elastic structure which elastically presses the terminal plate toward the cell stack body is provided between the insulator and the terminal plate.

A domestic power plant has a housing which has an external air connection and an output air connection, and comprises a ventilation device with a heat exchanger. The ventilation device is connected to the external air connection such that external air can flow in a first air tract via the heat exchanger, or via an external air bypass past the heat exchanger, into a feed air tract of the domestic power plant. The feed air tract runs at least partially within the housing. The domestic power plant also has an exhaust air tract in which an air volume flow, brought about by the ventilation device, can be propagated within the housing and a fuel cell unit.

A domestic power plant has a housing which has an external air connection and an output air connection, and comprises a ventilation device with a heat exchanger. The ventilation device is connected to the external air connection such that external air can flow in a first air tract via the heat exchanger, or via an external air bypass past the heat exchanger, into a feed air tract of the domestic power plant. The feed air tract runs at least partially within the housing. The domestic power plant also has an exhaust air tract in which an air volume flow, brought about by the ventilation device, can be propagated within the housing and a fuel cell unit.

Solid polymer electrolyte fuel cell stacks require a significant nominal compressive loading for proper operation and sealing. This loading is typically provided using relatively thick end plates and tight straps. In certain fuel cell applications, one or more solid polymer electrolyte fuel cell stacks are secured in larger enclosures (e.g. for isolation and crashworthiness in automotive applications). The enclosures however can themselves be sturdy enough to provide the necessary loading on the fuel cell stacks within. The present invention takes advantage of that to allow for use of thinner end plates and/or weaker straps which would otherwise be insufficient for use.

A fuel cell battery includes a plurality of stacks. Each of the stacks is a module containing a cell, and a base plate and a cover plate sandwiching the cell therebetween. In a state where the stacks are stacked together with a gasket being sandwiched between two adjacent stacks of the stacks, the two adjacent stacks are connected to each other by a connecting bolt. The gasket has, at a central part thereof, a contact plate that is elastic and electrically conductive. When the gasket is sandwiched between the two adjacent stacks, the contact plate is brought into abutment with the cover plate and the base plate.

A fuel cell vehicle that reduces damage on a fuel gas pump and deformation of a dash panel toward a cabin side when the vehicle collides head-on. The fuel gas pump is secured to a stack frame via a bracket such that a rotation, axis line of a motor adapted to drive a fuel gas pump inclines with respect to a reference line along the from-rear direction of the vehicle in plan view of the vehicle. Two fastening members secure the stack frame to the bracket in a state of being respectively inserted through a through hole and a cutout portion formed at a mounting portion. The cutout portion is formed such that, when the bracket turns together with the fuel gas pump with respect to the stack frame using one fastening member as a rotational center, the other fastening member exits out of an opening of the cutout portion.

An electrochemical arrangement with two metallic separator plates which each define a plate plane and which are stacked in a stack direction perpendicular to the plate planes. The separator plates comprise sealing elements which are embossed into the separator plate and which are supported against one another for sealing the electrochemical cell which is arranged between the separator plates and which are reversibly deformable in the stack direction up to a distance z.sub.2. The arrangement further comprises at least one support element which is arranged between the separator plates and which is distanced to the sealing elements of the separator plates in a direction parallel to the plate planes.