Provided is a method for manufacturing a lighter separator for fuel cell that suppresses problems during the forming. The method forms a separator for fuel cell, and the separator includes a flow-channel part that defines a flow channel of fluid, and a seal part that surrounds the flow-channel part and seals the fluid. The method includes: an embedding step of embedding wire members in uncured thermosetting resin containing conductive particles; and a forming step of curing the thermosetting resin having the wire members embedded therein in a die to form the separator.

An electrochemical reaction unit including a unit cell including an electrolyte layer, and a cathode and an anode that face each other in a first direction with the electrolyte layer intervening therebetween; and a felt member containing a ceramic material or a metal and a silica component. The felt member has an Si content of 0.9 mass % to 13.2 mass %. Also disclosed is an electrochemical reaction cell stack including a plurality of electrochemical reaction units, at least one of the units being the above-described electrochemical reaction unit.

A power generation cell includes a frame member. The frame member includes a first frame shaped sheet and a second frame shaped sheet that are joined together. The second frame shaped sheet is provided outside a cathode through a gap. A method of operating a fuel cell includes supplying a first reactant gas to a channel formed between the frame member and a first separator, a pressure of the first reactant gas being higher than a pressure of a second reactant gas, and supplying the second reactant gas to a channel formed between the frame member and a second separator.

A power generation cell includes a frame member. The frame member includes a first frame shaped sheet and a second frame shaped sheet that are joined together. The second frame shaped sheet is provided outside a cathode through a gap. A method of operating a fuel cell includes supplying a first reactant gas to a channel formed between the frame member and a first separator, a pressure of the first reactant gas being higher than a pressure of a second reactant gas, and supplying the second reactant gas to a channel formed between the frame member and a second separator.

The invention relates to a method for producing a polymer electrolyte membrane/electrode assembly for a fuel cell comprising the following steps: providing a first reinforcing membrane (14) comprising an opening (14a), a first electrode (12), a second reinforcing membrane (18) comprising an opening (18a), a second electrode (20), and a polymer electrolyte membrane (16), and arranging the first (14) and second (18) reinforcing membranes, the first (12) and second (20) electrodes and the polymer electrolyte membrane (16) so as to obtain a successive stack of the first electrode (12), the first reinforcing membrane (14), the polymer electrolyte membrane (16), the second reinforcing membrane (18) and the second electrode (20).

The invention relates to a method for producing a polymer electrolyte membrane/electrode assembly for a fuel cell comprising the following steps: providing a first reinforcing membrane (14) comprising an opening (14a), a first electrode (12), a second reinforcing membrane (18) comprising an opening (18a), a second electrode (20), and a polymer electrolyte membrane (16), and arranging the first (14) and second (18) reinforcing membranes, the first (12) and second (20) electrodes and the polymer electrolyte membrane (16) so as to obtain a successive stack of the first electrode (12), the first reinforcing membrane (14), the polymer electrolyte membrane (16), the second reinforcing membrane (18) and the second electrode (20).

A flat-plate-type fuel cell stack including a plurality of plate-shaped stacked fuel cells each including an electrolyte layer, an anode, and a cathode. The fuel cell stack includes at least one of a fuel manifold communicating with a space adjacent to the anode and an oxidant manifold communicating with a space adjacent to the cathode. A compression seal member and a glass seal member are disposed around the at least one manifold.

A flat-plate-type fuel cell stack including a plurality of plate-shaped stacked fuel cells each including an electrolyte layer, an anode, and a cathode. The fuel cell stack includes at least one of a fuel manifold communicating with a space adjacent to the anode and an oxidant manifold communicating with a space adjacent to the cathode. A compression seal member and a glass seal member are disposed around the at least one manifold.

The manufacturing method of the present invention is to manufacture a fuel cell stack by heating a stack of fuel cell single cells each of which includes organic substance-containing inorganic sealing members, a separator, an anode electrode, an electrolyte and a cathode electrode. The organic substance in the organic substance-containing inorganic sealing members is removed by heating the stack while supplying an oxygen-containing gas to fuel channels on the anode electrode side and externally applying an electric current so as to migrate charges from the anode electrode to the cathode electrode.

The manufacturing method of the present invention is to manufacture a fuel cell stack by heating a stack of fuel cell single cells each of which includes organic substance-containing inorganic sealing members, a separator, an anode electrode, an electrolyte and a cathode electrode. The organic substance in the organic substance-containing inorganic sealing members is removed by heating the stack while supplying an oxygen-containing gas to fuel channels on the anode electrode side and externally applying an electric current so as to migrate charges from the anode electrode to the cathode electrode.