Patent ID: 8268503

Claim:
A fuel cell stack formed by stacking a first electrolyte electrode assembly, a second electrolyte electrode assembly, and a plurality of separators alternately in a stacking direction, said first electrolyte electrode assembly and said second electrolyte electrode assembly each comprising a pair of electrodes and an electrolyte interposed between said electrodes, said plurality of separators comprising a first reactant gas passage as a passage of a first reactant gas and a second reactant gas passage as a passage of a second reactant gas, which is different from the first reactant gas, extending through said plurality of separators in the stacking direction, said fuel cell stack comprising: a first reactant flow field for supplying the first reactant gas along a first electrode surface of said first electrolyte electrode assembly; and a second reactant gas flow field for supplying the first reactant gas along a first electrode surface of said second electrolyte electrode assembly, wherein two of said plurality of separators sandwich said first electrolyte electrode assembly; one of said plurality of separators is adjacent to said second electrolyte electrode assembly; a first reactant gas distribution section connecting said first reactant gas flow field to said first reactant gas passage is formed between the two separators sandwiching said first electrolyte electrode assembly, wherein the first reactant gas distribution section is located between the first reactant gas passage and the first reactant gas flow field, and extends along a surface of the separator having the first electrode surface in a direction perpendicular to the stacking direction of the fuel cell stack; and the separator adjacent to said second electrolyte electrode assembly has a first opening for passing the first reactant gas therethrough such that said second reactant gas flow field is connected to said first reactant gas distribution section, wherein the first reactant gas distribution section connects to the first reactant gas passage at a first end and connects to the first reactant gas flow field at a second end, the first reactant gas flow field extends along a surface of the separator in a first direction; and the first opening extends through a surface of the separator adjacent to the second electrolyte electrode assembly in the stacking direction, and is provided at the second end of the first reactant gas distribution section between the first reactant gas flow field and the first reactant gas passage in the first direction along the surface of the separator that includes the first reactant gas flow field.