A load receiver member of a fuel cell separator member of a fuel cell stack includes an attachment portion disposed between an outer peripheral portion of a first metal separator and an outer peripheral portion of a second metal separator, and a tab continuous with the attachment portion and protruding from an outer peripheral portion of a joint separator. The attachment portion is joined to the outer peripheral portion of the joint separator by a joint portion.

A load receiver member of a fuel cell separator member of a fuel cell stack includes an attachment portion disposed between an outer peripheral portion of a first metal separator and an outer peripheral portion of a second metal separator, and a tab continuous with the attachment portion and protruding from an outer peripheral portion of a joint separator. The attachment portion is joined to the outer peripheral portion of the joint separator by a joint portion.

The present disclosure relates to a fuel cell hot box for improving the system efficiency of a fuel cell, wherein all of a fuel cell stack part, an afterburner, a reformer, and an air-heat exchange unit are provided inside a main chamber, fuel may be reformed and preheated using heat of the fuel cell stack part and heat of combustion gas generated by the afterburner, and at the same time, air may be also preheated. Thus, wasting energy can be prevented, the lifetime of the entire system can be increased by cooling the fuel cell stack part and increasing the durability of the fuel cell stack part against thermal stress, and a plurality of fuel cell stack parts share the center chamber, thereby simplifying a configuration of the fuel cell hot box. Further, since the reformer is configured to be vertically slidable, a heat exchange area of the reformer may be controlled in a predetermined manner, and thus a flexible system that may adjust a reforming rate of the fuel according to an operation state of the fuel cell may be configured.

A fuel cell system mounted in a vehicle includes a stack case for housing a fuel cell stack. In the stack case, a rear opening is formed in a rear portion facing backward. A cell voltage detection terminal electrically connected to an electrode of the fuel cell stack is exposed in the rear opening. A multilayer filter is provided in the rear opening. The multilayer filter has an inner mesh member, a filter member, and an outer mesh member. An electrical equipment housing case for housing electrical equipment faces the rear opening.

A fuel cell system mounted in a vehicle includes a stack case for housing a fuel cell stack. In the stack case, a rear opening is formed in a rear portion facing backward. A cell voltage detection terminal electrically connected to an electrode of the fuel cell stack is exposed in the rear opening. A multilayer filter is provided in the rear opening. The multilayer filter has an inner mesh member, a filter member, and an outer mesh member. An electrical equipment housing case for housing electrical equipment faces the rear opening.

A gasket is arranged between a fastening portion of an end plate arranged at an end in a cell stacking direction of a cell stack of a fuel cell and a case covering a periphery of the cell stack. The gasket is configured to seal a gap between the fastening portion and the gasket and a gap between the case and the gasket. The gasket includes a base plate and an elastic material layer. The base plate has a slope section that connects an inner peripheral section and an outer peripheral section to each other. The inner peripheral section and the outer peripheral section are located at different positions in a thickness direction of the base plate. The slope section is inclined with respect to the inner peripheral section and the outer peripheral section.

A container for a fuel cell system includes a system frame configured to house one or more components of a fuel cell system. The container also includes a plurality of fuel cells supported by the system frame and configured to provide power to an external unit. The container also includes a raised floor configured to support the plurality of fuel cells. The container also includes a cooling system. The cooling system includes a central cooling pipe located underneath the raised floor, a plurality of fuel cell cooling pipes connected to the central cooling pipe and to each fuel cell, and a cooling pipe valve configured to regulate the pressure of the cooling system.

A cell including: a body having a first end portion and a second end portion; a first electrode layer electrically connected to the body; a solid electrolyte layer located on the first electrode layer; and a second electrode layer located on the solid electrolyte layer, wherein the body includes a plurality of gas-flow passages passing through the body from the first end portion to the second end portion; and the plurality of gas-flow passages include: one or more center-shifted gas-flow passages that include: a central portion and a first end portion; wherein a center of the one or more center-shifted gas-flow passages at the central portion is laterally shifted from a center of the one or more center- shifted gas-flow passages at the first end portion and a diameter of the one or more center-shifted gas-flow passages gradually increases from the central portion to the first end portion.

A cell including: a body having a first end portion and a second end portion; a first electrode layer electrically connected to the body; a solid electrolyte layer located on the first electrode layer; and a second electrode layer located on the solid electrolyte layer, wherein the body includes a plurality of gas-flow passages passing through the body from the first end portion to the second end portion; and the plurality of gas-flow passages include: one or more center-shifted gas-flow passages that include: a central portion and a first end portion; wherein a center of the one or more center-shifted gas-flow passages at the central portion is laterally shifted from a center of the one or more center- shifted gas-flow passages at the first end portion and a diameter of the one or more center-shifted gas-flow passages gradually increases from the central portion to the first end portion.

An energy supply apparatus may be modular and can be used underwater. In some examples, the modules comprise pressure vessels. The modules are chosen independently of each other from a group comprising a battery module, a fuel cell module, and air-independent Diesel module. The pressure vessels may be cylindrical and may have spherical segments disposed at ends segments of the pressure vessels. One or more of the spherical segments of the pressure vessels may be configured to be swiveled. Modules that are configured as battery modules may include battery elements, an inverter, a battery monitoring system, a separating unit, a control unit, a transformer, and/or a cooling unit.