A cell structure for a fuel cell including: power generation cell assemblies each including a power generation cell which includes a fuel electrode, an oxidant electrode, and an electrolyte sandwiched therebetween and is configured to generate power by using supplied gases; a separator configured to separate the adjacent power generation cell assemblies from each other; a sealing member disposed between an edge of a corresponding one of the power generation cell assemblies and an edge of the separator and configured to retain any of the gases supplied to the power generation cells between the corresponding power generation cell assembly and the separator; and a heat exchange part disposed adjacent to the sealing member and configured to perform temperature control of the sealing member by using any of the gases supplied to the power generation cells.

A fuel cell stack includes: a cell stacked body in which fuel cells are stacked in multiple layers; an end plate by which the fuel cells are fastened; and a dummy cell interposed between the cell stacked body and the end plate, wherein the end plate includes a gas inlet for introducing a reactant gas from an outside, and a gas outlet for discharging the reactant gas to the outside, and the dummy cell includes a gas supply manifold delivering the reactant gas having passed through the gas inlet to the cell stacked body, a gas exhaust manifold delivering the reactant gas having passed through the cell stacked body to the gas outlet, and a bypass channel connecting the gas supply manifold to the gas exhaust manifold and being partially curved to allow the condensed water to be collected.

Herein disclosed is an electrochemical reactor comprising at least one unit, wherein the unit comprises an interconnect, an anode, a cathode, an electrolyte between the anode and the cathode and wherein the unit has a thickness of no greater than 1 mm. Disclosed also herein is an electrochemical reactor comprising an anode no greater than 50 microns in thickness, a cathode no greater than 50 microns in thickness, and an electrolyte no greater than 10 microns in thickness, wherein the electrolyte is between the anode and the cathode.

Various embodiments may provide a method of forming an energy conversion device. The method may include forming an electrolyte layer on the first surface of the semiconductor substrate. The method may also include forming a cavity on the second surface of the semiconductor substrate using a deep reactive ion etch. The method may further include enlarging said cavity by carrying out one or more wet etches so that the enlarged cavity is at least partially defined by a vertical arrangement comprising a first lateral cavity surface of the semiconductor substrate extending substantially along a first direction, and a second lateral cavity surface of the semiconductor substrate adjoining the first lateral cavity surface. The method may include forming a first electrode on a first surface of the electrolyte layer, and forming a second electrode on a second surface of the electrolyte layer.

An assembly, including: an electrolyte membrane; and a frame that holds the electrolyte membrane, wherein the frame includes a first frame that holds one surface of the electrolyte membrane, and a second frame that holds the other surface of the electrolyte membrane, the frame further has a joint part that joins the first frame and the second frame, and the joint part has a projection.

A low temperature co-fired ceramic substrate miniature fuel cell and manufacturing method therefor is disclosed. The method can be used for rapid, flexible and precise fabrication of gas distribution network as well as for a conventional membrane electrode assembly, for providing high power density. The construction results in a light weight assembly offering 5 optimum cavity for robust set-up and planar series configuration as compared to other established methods of fabrication.

A cooling system for cooling electrochemical cells of a battery system is provided. The cooling system includes a housing configured to accommodate a plurality of stacked electrochemical cells. The housing includes a structured side wall having a protrusion therein, and the protrusion is adapted to receive a section of a thermally conductive element arranged between two adjacent ones of the stacked electrochemical cells.

A manifold includes first and second manifold main bodies. The first manifold main body includes a gas supply chamber that is connected to a first gas channel, and the second manifold main body includes a gas collection chamber that is connected to a second gas channel. The first manifold main body includes a first top plate, a first bottom plate, and a first side plate. The first top plate includes a first through hole for connecting the first gas channel and the gas supply chamber. The second manifold main body includes a second top plate, a second bottom plate, and a second side plate. The second top plate includes a second through hole for connecting the second gas channel and the gas collection chamber. The first bottom plate and the second bottom plate are constituted by members that are separate from each other.

A fuel cell stack includes: a cell stacked body in which fuel cells are stacked in multiple layers; an end plate by which the fuel cells are fastened; and a dummy cell interposed between the cell stacked body and the end plate, wherein the end plate includes a gas inlet for introducing a reactant gas from an outside, and a gas outlet for discharging the reactant gas to the outside, and the dummy cell includes a gas supply manifold delivering the reactant gas having passed through the gas inlet to the cell stacked body, a gas exhaust manifold delivering the reactant gas having passed through the cell stacked body to the gas outlet, and a bypass channel connecting the gas supply manifold to the gas exhaust manifold and being partially curved to allow the condensed water to be collected.

Bonding dies for producing a fuel cell that can suppress floating of a portion of a resin frame bonded to a membrane electrode assembly. The dies include first and second dies that face and contact one separator and the other separator, respectively. The first die includes a central receiving portion that receives a central region of the one separator, and an outer periphery receiving portion that receives a to-be-welded region of the one separator. The second die includes an inner die that pressurizes a central region of the other separator, and an outer die formed to surround the inner die and adapted to thermally compress a to-be-welded region of the other separator to be welded to the resin frame. The inner die extends from a portion corresponding to the central region along an open edge in the resin frame, up to a region closer to the outer periphery side of the electrode assembly than to the portion of the resin frame bonded to the membrane electrode assembly, so as to pressurize the resin frame via the other separator.