| CPC H01M 8/04201 (2013.01) [H01M 8/1004 (2013.01); H01M 8/2475 (2013.01); H01M 8/2483 (2016.02); H01M 2250/20 (2013.01)] | 4 Claims |
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1. A fuel cell stack comprising a cell stack body, and a terminal plate, a first insulating plate, a second insulating plate and an end plate which are disposed at one end of the cell stack body, the cell stack body comprising a plurality of power generation cells stacked one another, each of the power generation cells comprising a membrane electrode assembly and separators with the membrane electrode assembly interposed between the separators, the membrane electrode assembly comprising an electrolyte membrane with an anode and a cathode with the electrolyte membrane interposed between the anode and the cathode,
wherein the first insulating plate is arranged between the cell stack body and the second insulating plate,
a reactant gas supply passage for supplying a reactant gas to the anode or the cathode, an upper reactant gas discharge passage and a lower reactant discharge passage both for discharging a remainder of the reactant gas having been consumed at the anode or the cathode extend, in a stacking direction, through at least the cell stack body, the first insulating plate, the second insulating plate and the end plate,
the reactant gas supply passage is disposed at a first end of the cell stack body in a horizontal direction, and
the upper reactant gas discharge passage is disposed at a second end of the cell stack body in the horizontal direction at a position higher than the reactant gas supply passage, and
the lower reactant gas discharge passage is disposed at the second end of the cell stack body in the horizontal direction at a position lower than the reactant gas supply passage,
the reactant gas supply passage in the first insulating plate is a first plate passage, and
the reactant gas supply passage in the second insulating plate is a second plate passage,
a bypass channel is formed between the first insulating plate and the second insulating plate and connects the second plate passage to the lower reactant gas discharge passage,
an annular protrusion protruding toward the second plate passage is disposed around the first plate passage, and forms an inlet of the bypass channel with the second insulating plate,
the annular protrusion includes an internal space defining a part of the first plate passage,
a lower portion of an inner surface of the first plate passage comprises an inclined section that is inclined upward toward a downstream of the reactant gas, and
the inclined section is provided in an upstream part of the first plate passage at a lowest point of the inner surface at a protruding end of the annular protrusion.
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