A drying method of a fuel cell includes holding the fuel cell having separator plates exposed on the surface of the fuel cell at a predetermined angle, and blowing air to the fuel cell at an angle in a range of 5° or larger and 85° or smaller with respect to the surface of the separator plate of the fuel cell held at the predetermined angle.

A drying method of a fuel cell includes holding the fuel cell having separator plates exposed on the surface of the fuel cell at a predetermined angle, and blowing air to the fuel cell at an angle in a range of 5° or larger and 85° or smaller with respect to the surface of the separator plate of the fuel cell held at the predetermined angle.

The bipolar separator is formed by the superimposition of two distribution plates and two cooling plates, the two cooling plates being arranged between the two distribution plates, each distribution plate having an outer face and an inner face, the outer face of each distribution plate being provided with distribution channels for the flow of a reactive fluid, the cooling plates defining internal conduits for the circulation of a cooling fluid.

The bipolar separator is formed by the superimposition of two distribution plates and two cooling plates, the two cooling plates being arranged between the two distribution plates, each distribution plate having an outer face and an inner face, the outer face of each distribution plate being provided with distribution channels for the flow of a reactive fluid, the cooling plates defining internal conduits for the circulation of a cooling fluid.

A separator for a fuel cell includes a contact surface configured to contact a power generating unit of the fuel cell. Groove passages are arranged side by side in the contact surface. Reactant gas flows through the groove passages. At least one of the groove passages includes a wavy section that extends in a wavy shape in planar directions of the contact surface. An upstream portion and a downstream portion in a flow direction of the reactant gas in each groove passage are defined as an upstream portion and a downstream portion, respectively. A wavelength of the wavy section is smaller in the downstream portion than in the upstream portion.

A separator for a fuel cell includes a contact surface configured to contact a power generating unit of the fuel cell. Groove passages are arranged side by side in the contact surface. Reactant gas flows through the groove passages. At least one of the groove passages includes a wavy section that extends in a wavy shape in planar directions of the contact surface. An upstream portion and a downstream portion in a flow direction of the reactant gas in each groove passage are defined as an upstream portion and a downstream portion, respectively. A wavelength of the wavy section is smaller in the downstream portion than in the upstream portion.

The invention relates to a fuel cell stack (100) having at least one fuel cell (101) which has a membrane (CCM) for separating an anode side (A) of the fuel cell (101) from a cathode side (K) of the fuel cell (101), an anode-side gas diffusion layer (GDLA), a cathode-side gas diffusion layer (GDLK) and a bipolar plate (BPP) for separating the fuel cell (101) from an adjacent fuel cell (101) or a housing. According to the invention, the membrane (CCM) protrudes beyond the anode-side gas diffusion layer (GDLA) and the cathode-side gas diffusion layer (GDLK) in an edge region (R) located outside an active area (AF) of the membrane (CCM), and the membrane (CCM) has a centering dam (10) in the edge region (R) of the anode side (A) or of the cathode side (K).

The invention relates to a fuel cell stack (100) having at least one fuel cell (101) which has a membrane (CCM) for separating an anode side (A) of the fuel cell (101) from a cathode side (K) of the fuel cell (101), an anode-side gas diffusion layer (GDLA), a cathode-side gas diffusion layer (GDLK) and a bipolar plate (BPP) for separating the fuel cell (101) from an adjacent fuel cell (101) or a housing. According to the invention, the membrane (CCM) protrudes beyond the anode-side gas diffusion layer (GDLA) and the cathode-side gas diffusion layer (GDLK) in an edge region (R) located outside an active area (AF) of the membrane (CCM), and the membrane (CCM) has a centering dam (10) in the edge region (R) of the anode side (A) or of the cathode side (K).

Provided is a fuel cell stack that includes a plurality of fuel cells, the fuel cells stacking an anode electrode layer, a cathode electrode layer, and a solid electrolyte layer sandwiched between the anode electrode layer and the cathode electrode layer, the plurality of fuel cells being stacked having a separator disposed therebetween. The fuel cell stack includes a fuel channel through which fuel passes, the fuel channel formed between adjacent two of the fuel cells by the separator; and a U-turn channel configured to connect the fuel channel to the anode electrode layer. The fuel channel is formed extending in a stacking surface direction of the fuel cells, and the fuel channel includes heat balance adjusting means configured to adjust heat balance of the fuel cells. The U-turn channel is formed to bend from one end of the fuel channel to the anode electrode layer.

Provided is a fuel cell stack that includes a plurality of fuel cells, the fuel cells stacking an anode electrode layer, a cathode electrode layer, and a solid electrolyte layer sandwiched between the anode electrode layer and the cathode electrode layer, the plurality of fuel cells being stacked having a separator disposed therebetween. The fuel cell stack includes a fuel channel through which fuel passes, the fuel channel formed between adjacent two of the fuel cells by the separator; and a U-turn channel configured to connect the fuel channel to the anode electrode layer. The fuel channel is formed extending in a stacking surface direction of the fuel cells, and the fuel channel includes heat balance adjusting means configured to adjust heat balance of the fuel cells. The U-turn channel is formed to bend from one end of the fuel channel to the anode electrode layer.