JP4634737B2 - Fuel cell stack - Google Patents

Description

  The present invention relates to a fuel cell stack including a power generation cell in which an electrolyte / electrode structure in which an electrolyte is disposed between a pair of electrodes and a metal separator are stacked, and a plurality of the power generation cells are stacked.

  For example, in a polymer electrolyte fuel cell, an electrolyte / electrode structure in which an anode side electrode and a cathode side electrode are provided on both sides of an electrolyte (electrolyte membrane) made of a polymer ion exchange membrane is sandwiched by separators. Has a cell. This type of fuel cell is normally used as a fuel cell stack by stacking a predetermined number of power generation cells.

  In the surface of the separator, a reaction gas flow channel is provided for flowing a reaction gas so as to face each electrode, and a cooling medium for cooling the power generation cell is passed between separators constituting adjacent power generation cells. A cooling medium flow path is provided. The reactive gas is an oxidant gas and a fuel gas, the reactive gas flow path is an oxidant gas flow path for flowing the oxidant gas to the cathode side electrode, and a fuel gas for flowing the fuel gas to the anode side electrode. And a flow path.

  On the other hand, at the peripheral edge of the separator, there are provided a fuel gas supply communication hole and a fuel gas discharge communication hole, which are reaction gas communication holes that penetrate in the stacking direction of the separator and communicate with the fuel gas flow path, and an oxidant gas flow path. An oxidant gas supply communication hole and an oxidant gas discharge communication hole, which are reaction gas communication holes communicating with each other, and a cooling medium supply communication hole and a cooling medium discharge communication hole communicating with the cooling medium flow path are formed.

  In this case, a metal separator is used to reduce the thickness and weight of the separator. At that time, the metal separator is provided with various flow paths and communication holes by pressing, and a seal member having a sealing function and an insulating function is integrally formed in the metal separator.

  For example, the PEM fuel cell disclosed in Patent Document 1 includes an uncooled fuel cell 1a and a cooled fuel cell 1b as shown in FIG. The uncooled fuel cell 1a has a stacked MEA 2a, a seal 3a, a bipolar plate 4a, and a seal 5a. The cooled fuel cell 1b includes an MEA 2b, a seal 3b, a bipolar plate 4b, a spacer 6, a bipolar plate 4c, and a seal 5b.

  An opening 7 is formed so as to penetrate in the stacking direction (arrow X direction) of the PEM fuel cell, and the opening 7 is connected to the bipolar electrode through a fluid communication path 8 formed between the bipolar plates 4b and 4c. The anode port 9 of the plate 4b communicates with a fluid communication path 8b provided above the bipolar plate 4b.

  Therefore, the fuel flows along the fluid communication path 8a formed by the bipolar plates 4b and 4c and the spacer 6 through the opening 7, and then passes through the anode port 9 to pass through the MEA 2b, the seal 3b, and the bipolar plate 4b. The fuel is supplied to the anode surface of the MEA 2b by flowing along the fluid communication path 8b formed by the above.

JP 2002-260690 A (FIG. 10)

  In the PEM fuel cell, the uncooled fuel cell 1a and the cooled fuel cell 1b are clamped and held by a predetermined clamping load in the stacking direction (arrow X direction). At this time, for example, in the cooled fuel cell 1b, the bipolar plates 4b and 4c are configured to be thin, and pressure is applied to the bipolar plates 4b and 4c through the seals 3b and 5b and the spacer 6. Is done.

  Therefore, the fluid communication paths 8a and 8b cannot withstand the applied pressure, and there is a problem that the bipolar plates 4b and 4c are deformed corresponding to the flow path areas P1 and P2. As a result, problems such as the fluid communication passages 8a and 8b being blocked and the pressure loss of the fuel being increased occur.

  The present invention solves this type of problem, and is a fuel that can effectively prevent deformation of a metal separator with a simple and economical configuration, and can ensure a desired sealing function and power generation performance. An object is to provide a battery stack.

  The present invention includes a power generation cell in which an electrolyte / electrode structure in which an electrolyte is disposed between a pair of electrodes and a metal separator are stacked, and a plurality of the power generation cells are stacked to form a stack, and the electrolyte / electrode A reaction gas flow path for supplying a reaction gas along the electrode surface is provided between the structure and the metal separator, and a cooling medium is supplied between the power generation cells between the power generation cells. It is a fuel cell stack provided with a cooling medium flow path.

  The metal separator is provided with a plurality of guide portions for forming a fluid passage between the metal separators or between the metal separator and the electrolyte / electrode structure, and the metal separator has the plurality of guide portions. Corresponding to the area to be provided, it has integrally a concave or convex shaped part.

  The power generation cell is provided with a reaction gas communication hole that penetrates in the stacking direction and communicates with the reaction gas channel, and the metal separator guides the reaction gas from the reaction gas communication hole to the reaction gas channel. Preferably, a plurality of guide portions are provided.

  Further, the reaction gas flow path is provided on one surface of the metal separator, and the reaction gas communication hole is formed from the other surface of the metal separator through the reaction gas introduction hole formed through the metal separator. It is preferable that a plurality of guide portions that guide the reaction gas from the reaction gas communication hole to the reaction gas introduction hole are provided on the other surface of the metal separator while communicating with the reaction gas channel.

  Furthermore, it is preferable that the shaping | molding part is extended in the sequence direction of a some guide part, and the said some guide part is integrally molded by the metal separator via the recessed part of the said shaping | molding part.

  The power generation cell is provided with a cooling medium communication hole that penetrates in the stacking direction and communicates with the cooling medium flow path, and the metal separator guides the cooling medium from the cooling medium communication hole to the cooling medium flow path. Preferably, a plurality of guide portions are provided.

  In the present invention, the metal separator is provided with a concave or convex molded part, and this molded part functions as a reinforcing part of the metal separator. For this reason, when the fuel cell stack is tightened in the stacking direction, and the pressing force is applied to the metal separator by the plurality of guide portions, the molding portion corresponding to the plurality of guide portions can reliably receive the pressing force. it can.

  Therefore, the deformation of the metal separator does not block the reaction gas flow path, and the gas pressure loss may increase, or the linear pressure of the seal may fluctuate to cause leakage of the reaction gas or the cooling medium. Absent. Thereby, it is possible to satisfactorily prevent the metal separator from being deformed with a simple and economical configuration, and to secure a desired sealing function and power generation performance.

  FIG. 1 is an exploded perspective view of a main part of a power generation cell 12 constituting a fuel cell 10 according to an embodiment of the present invention, and FIG. 2 is a stack in which a plurality of power generation cells 12 are stacked in the direction of arrow A. FIG. 3 is an explanatory cross-sectional view of a main part of the fuel cell 10 and FIG.

  As shown in FIGS. 2 and 3, the fuel cell 10 has a plurality of power generation cells 12 stacked in the direction of arrow A, and end plates 14 a and 14 b are disposed at both ends in the stacking direction. The end plates 14a and 14b are fixed via tie rods (not shown), whereby a predetermined tightening load is applied to the stacked power generation cells 12 in the arrow A direction.

  As shown in FIG. 1, in the power generation cell 12, an electrolyte membrane / electrode structure (electrolyte / electrode structure) 16 is sandwiched between first and second metal separators 18 and 20. The first and second metal separators 18 and 20 are made of, for example, a steel plate, a stainless steel plate, an aluminum plate, a plated steel plate, or a metal plate whose surface is subjected to anticorrosion treatment, and has a thickness. For example, it is set within a range of 0.05 mm to 1.0 mm.

  One end edge of the power generation cell 12 in the direction of arrow B (the horizontal direction in FIG. 1) communicates with each other in the direction of arrow A, which is the stacking direction, and oxidant for supplying an oxidant gas, for example, an oxygen-containing gas. An agent gas inlet communication hole 30a, a cooling medium outlet communication hole 32b for discharging a cooling medium, and a fuel gas outlet communication hole 34b for discharging a fuel gas, for example, a hydrogen-containing gas, are provided in the direction of arrow C (vertical direction). Are provided in an array.

  The other end edge of the power generation cell 12 in the direction of arrow B communicates with each other in the direction of arrow A, a fuel gas inlet communication hole 34a for supplying fuel gas, and a cooling medium inlet communication hole for supplying a cooling medium. 32a and oxidant gas outlet communication holes 30b for discharging the oxidant gas are arranged in the direction of arrow C.

  The electrolyte membrane / electrode structure 16 includes, for example, a solid polymer electrolyte membrane 36 in which a perfluorosulfonic acid thin film is impregnated with water, and an anode side electrode 38 and a cathode side electrode 40 that sandwich the solid polymer electrolyte membrane 36. With. The anode side electrode 38 has a smaller surface area than the cathode side electrode 40.

  The anode side electrode 38 and the cathode side electrode 40 are composed of a gas diffusion layer made of carbon paper or the like, and an electrode catalyst layer in which porous carbon particles having a platinum alloy supported on the surface are uniformly applied to the surface of the gas diffusion layer. And have. The electrode catalyst layer is bonded to both surfaces of the solid polymer electrolyte membrane 36.

  On the surface 18a of the first metal separator 18 on the electrolyte membrane / electrode structure 16 side, for example, an oxidant gas flow path (reactive gas flow path) 42 extending in the vertical direction while meandering in the direction of arrow B is provided. (See FIGS. 1 and 4). As shown in FIG. 5, the surface 20a of the second metal separator 20 on the electrolyte membrane / electrode structure 16 side communicates with a fuel gas inlet communication hole 34a and a fuel gas outlet communication hole 34b, as will be described later. A fuel gas channel (reactive gas channel) 44 extending in the vertical upward direction (arrow C direction) while meandering in the direction of arrow B is formed.

  As shown in FIGS. 1 and 6, the cooling medium inlet communication hole 32a and the cooling medium outlet communication hole 32b communicate with each other between the surface 18b of the first metal separator 18 and the surface 20b of the second metal separator 20. A cooling medium flow path 46 is formed. The cooling medium flow path 46 extends linearly in the direction of arrow B.

  As shown in FIGS. 1 and 4, the first seal member 50 is integrated with the surfaces 18 a and 18 b of the first metal separator 18 around the outer peripheral end of the first metal separator 18. The first seal member 50 uses, for example, a seal material such as EPDM, NBR, fluorine rubber, silicone rubber, fluorosilicone rubber, butyl rubber, natural rubber, styrene rubber, chloroplane, or acrylic rubber, a cushion material, or a packing material. To do.

  The first seal member 50 includes a first flat portion 52 that is integrated with the surface 18 a of the first metal separator 18, and a second flat portion 54 that is integrated with the surface 18 b of the first metal separator 18.

  As shown in FIG. 2, the first flat portion 52 circulates around the outer peripheral end of the electrolyte membrane / electrode structure 16, while the second flat portion 54 has a position where the cathode side electrode 40 is superposed over a predetermined range. Go around. As shown in FIG. 4, the first flat portion 52 is formed by connecting the oxidant gas inlet communication hole 30 a and the oxidant gas outlet communication hole 30 b to the oxidant gas flow path 42, while the second flat portion 54. Is formed by communicating the cooling medium inlet communication hole 32a and the cooling medium outlet communication hole 32b.

  The second seal member 56 is integrated with the surfaces 20 a and 20 b of the second metal separator 20 around the outer peripheral end of the second metal separator 20. The second seal member 56 includes an outer seal (communication hole seal) 58a provided on the surface 20a in the vicinity of the outer peripheral end of the second metal separator 20, and is spaced inward from the outer seal 58a by a predetermined distance. Then, an inner seal (electrode seal) 58b is provided.

  The outer seal 58a contacts the first flat portion 52 provided on the first metal separator 18, while the inner seal 58b directly contacts the solid polymer electrolyte membrane 36 constituting the electrolyte membrane / electrode structure 16. .

  As shown in FIG. 5, the outer seal 58a includes an oxidant gas inlet communication hole 30a, a cooling medium outlet communication hole 32b, a fuel gas outlet communication hole 34b, a fuel gas inlet communication hole 34a, a cooling medium inlet communication hole 32a, and an oxidant. The gas outlet communication hole 30b is surrounded. The inner seal 58b surrounds the fuel gas flow path 44, and an outer peripheral end portion of the electrolyte membrane / electrode structure 16 is disposed between the inner seal 58b and the outer seal 58a.

  An outer seal 58c corresponding to the outer seal 58a and an inner seal 58d corresponding to the inner seal 58b are provided on the surface 20b of the second metal separator 20 (see FIG. 6).

  As shown in FIG. 5, the outer seal 58 a includes an inlet connection portion 60 that connects the oxidant gas inlet communication hole 30 a and the oxidant gas flow path 42, an oxidant gas outlet communication hole 30 b, and the oxidant gas flow path. And an outlet connecting portion 62 that communicates with 42.

  The inlet connecting portion 60 is constituted by a plurality of guide portions 64 that are intermittently cut out in the direction of the arrow C along the outer seal 58a and extend in the direction of the arrow B. Each guide part 64 functions as a spacer, and a communication path (fluid path) for oxidizing gas is formed between the guide parts 64. The outlet connecting portion 62 includes a plurality of guide portions 66 extending in the direction of arrow B while partially cutting out the outer seal 58a, like the inlet connecting portion 60. A communication passage (fluid passage) for oxidizing gas is formed between the guide portions 66.

  As shown in FIG. 6, on the surface 20b of the second metal separator 20, an inlet connecting portion 72 that connects the cooling medium inlet communication hole 32a and the cooling medium flow path 46, the cooling medium outlet communication hole 32b, and the cooling medium. An outlet connecting portion 74 that communicates with the flow path 46 is provided. The inlet connecting portion 72 includes an outer seal 58c and an inner seal 58d, and is provided intermittently in the direction of arrow C, and includes a plurality of guide portions 76 extending in the direction of arrow B. Similarly, the outlet connecting portion 74 includes an outer seal 58c and an inner seal 58d, and is provided intermittently in the direction of arrow C, and includes a plurality of guide portions 78 extending in the direction of arrow B.

  In the surface 20b, an inlet connection portion 84 and an outlet connection portion 86 are provided in the vicinity of the fuel gas inlet communication hole 34a and the fuel gas outlet communication hole 34b. The inlet connecting portion 84 is provided with a plurality of guide portions 88 arranged in the direction of arrow C, while the outlet connecting portion 86 is similarly provided with a plurality of guide portions 90 arranged in the direction of arrow C.

  A plurality of supply hole portions 96 and discharge hole portions 98 are formed in the vicinity of the inlet connection portion 84 and the outlet connection portion 86, respectively, outside the inner seal 58d. As shown in FIG. 5, the supply hole portion 96 and the discharge hole portion 98 are formed through the surface 20a of the second metal separator 20 inward of the inner seal 58b and on the inlet side and the outlet side of the fuel gas passage 44. Is done. Inside the inner seal 58b, a plurality of guide portions 100, 102 are arranged in the direction of the arrow C in the vicinity of the supply hole portion 96 and the discharge hole portion 98, respectively.

  As shown in FIGS. 2 and 5 to 7, the second metal separator 20 has a convex shape (surface) on the surface 20 a side corresponding to a region where a plurality of guide portions 88 constituting the inlet connecting portion 84 is provided. A molded part 104 that is bent in a concave shape on the 20b side is integrally molded. The molding part 104 is located between the outer seal 58a and the inner seal 58b, and is provided so as to extend in the arrangement direction (arrow C direction) of the plurality of guide parts 88. The plurality of guide portions 88 are integrally formed by injection molding with the second metal separator 20 via the concave portion of the forming portion 104.

  As shown in FIG. 5, the second metal separator 20 is integrally formed with a convex molding portion 106 on the surface 20 a side corresponding to a region where a plurality of guide portions 90 constituting the outlet coupling portion 86 are provided. . The molding unit 106 is configured in the same manner as the molding unit 104 described above.

  As shown in FIGS. 3, 5, and 6, the second metal separator 20 is formed in a convex shape on the surface 20 b side corresponding to the region where the plurality of guide portions 64 constituting the inlet connecting portion 60 is provided. The portion 108 is integrally molded, and the convex shaped portion 110 is integrally formed on the surface 20b side corresponding to the region where the plurality of guide portions 66 constituting the outlet connecting portion 62 are provided. The molding portions 108 and 110 extend in the arrangement direction of the plurality of guide portions 64 and 66, respectively, and are provided between the outer seal 58c and the inner seal 58d. The plurality of guide portions 64 and 66 are integrally formed with the second metal separator 20 by injection molding via the concave portions of the molding portions 108 and 110.

  As shown in FIGS. 5 and 6, the second metal separator 20 has a plurality of guide portions 76 and 78 constituting the inlet connecting portion 72 and the outlet connecting portion 74, corresponding to the region provided on the surface 20 a side. The convex shaped parts 112 and 114 are integrally formed. The molding parts 112 and 114 extend in the arrangement direction of the plurality of guide parts 76 and 78, respectively, and are provided between the outer seal 58a and the inner seal 58b.

  As shown in FIGS. 1, 2, and 4, the first metal separator 18 protrudes toward the surface 18 b side corresponding to the region where the plurality of guide portions 100 and 102 of the second metal separator 20 are provided. The shaped portions 116 and 118 are integrally formed. The forming portions 116 and 118 are provided so as to extend in the arrangement direction of the plurality of guide portions 100 and 102, respectively.

  The operation of the fuel cell 10 configured as described above will be described below.

  First, as shown in FIG. 1, a fuel gas such as a hydrogen-containing gas is supplied to the fuel gas inlet communication hole 34a, and an oxidant gas such as an oxygen-containing gas is supplied to the oxidant gas inlet communication hole 30a. Further, a cooling medium such as pure water or ethylene glycol is supplied to the cooling medium inlet communication hole 32a.

  Therefore, the fuel gas is supplied from the fuel gas inlet communication hole 34a along the inlet connecting portion 84 through the surface 20b (the other surface) of the second metal separator 20 to the supply hole portion 96. Then, it is introduced into the fuel gas flow path 44 provided on the surface 20a (one surface) of the second metal separator 20 (see FIG. 2). The fuel gas moves vertically upward while meandering in the arrow B direction along the fuel gas flow path 44, and is supplied to the anode side electrode 38 constituting the electrolyte membrane / electrode structure 16.

  On the other hand, the oxidant gas is introduced from the oxidant gas inlet communication hole 30a through the inlet connecting portion 60 into the oxidant gas flow path 42 of the first metal separator 18 (see FIG. 3), and meanders in the direction of arrow B. It moves vertically upward and is supplied to the cathode side electrode 40 constituting the electrolyte membrane / electrode structure 16.

  Therefore, in each electrolyte membrane / electrode structure 16, the fuel gas supplied to the anode side electrode 38 and the oxidant gas supplied to the cathode side electrode 40 are consumed by an electrochemical reaction in the electrode catalyst layer. Power generation is performed.

  Next, the fuel gas consumed by being supplied to the anode side electrode 38 is discharged from the discharge hole portion 98 through the outlet connection portion 86 and along the fuel gas outlet communication hole 34b in the direction of arrow A. Similarly, the oxidant gas supplied to and consumed by the cathode side electrode 40 is discharged from the outlet connection part 62 in the direction of arrow A along the oxidant gas outlet communication hole 30b.

  The cooling medium supplied to the cooling medium inlet communication hole 32a is introduced into the cooling medium flow path 46 between the first and second metal separators 18 and 20 from the inlet connecting portion 72 and then flows in the direction of arrow B. (See FIG. 6). After cooling the electrolyte membrane / electrode structure 16, the cooling medium passes through the outlet connection portion 74 and is discharged from the cooling medium outlet communication hole 32 b.

  In this case, in this embodiment, as shown in FIGS. 5 to 7, for example, the plurality of guide portions 88 function as spacers in the inlet connection portion 84, thereby providing a space between the first and second metal separators 18 and 20. A fluid passage for supplying fuel gas is formed, and the fluid passage communicates with the fuel gas passage 44 through a plurality of supply holes 96. The second metal separator 20 is integrally formed with a convex shaped portion 104 on the side of the surface 20a corresponding to a region where the plurality of guide portions 88 are provided. The forming portion 104 functions as a reinforcing portion for preventing the deformation and the like from being generated by the applied pressure acting on the thin plate-shaped second metal separator 20 in particular.

  That is, in the fuel cell 10, a plurality of power generation cells are stacked in the direction of arrow A and a predetermined tightening load is applied between the end plates 14a and 14b disposed at both ends in the stacking direction, and functions as a spacer. Pressure is applied to the second metal separator 20 by the plurality of guide portions 88. On the other hand, an outer seal 58a and an inner seal 58b are spaced apart from each other by a predetermined distance on the surface 20a opposite to the guide portion 88, and a molding portion 104 is provided in this gap. Thereby, the shaping | molding part 104 can prevent reliably that the 2nd metal separator 20 deform | transforms with the clamping load of the fuel cell 10. FIG.

  FIG. 8 shows a result of measuring the surface pressure in the stacking direction of the power generation cells 12 along the arrangement direction of the guide portions 88 using the present embodiment and a comparative example in which the forming portion 104 is not provided. As a result, in the comparative example in which the molding portion 104 is not provided, the surface pressure is lost between the guide portions 88, the fuel gas pressure loss increases or the seal surface pressure fluctuates, and the fuel gas, the oxidant There is a risk of leakage of gas or cooling medium.

  On the other hand, in the present embodiment, the surface pressure is not lost and the second metal separator 20 is satisfactorily prevented from being deformed with a simple and economical configuration, and a desired sealing function and power generation performance are ensured. The effect that it becomes possible is acquired.

  Further, as shown in FIGS. 5 and 6, the outlet connecting portion 86 is provided with a molding portion 106 corresponding to a plurality of guide portions 90 forming a fuel gas discharge passage. For this reason, similarly to the above-described forming portion 104, the pressure applied by the guide portion 90 can be reliably received via the forming portion 106.

  On the other hand, molding portions 108 and 110 are provided corresponding to the plurality of guide portions 64 and 66, respectively, that form the supply passage and the discharge passage for the oxidizing gas. Further, molding portions 112 and 114 are provided corresponding to the plurality of guide portions 76 and 78 constituting the cooling medium supply passage and the discharge passage, respectively. Thereby, the second metal separator 20 does not cause deformation when the fuel cell 10 is configured and a tightening load is applied, and the second metal separator 20 can be advantageously thinned.

  Furthermore, the first metal separator 18 is provided with molding portions 116 and 118 corresponding to the plurality of guide portions 100 and 102 provided in the second metal separator 20. Accordingly, the first metal separator 18 having a thin plate shape is not deformed by the pressure applied by the guide portions 100 and 102, and a desired sealing function and power generation performance can be ensured.

It is a principal part disassembled perspective explanatory view of the power generation cell which constitutes the fuel cell concerning the embodiment of the present invention. It is principal part cross-sectional explanatory drawing of the said fuel cell. It is principal part cross-sectional explanatory drawing of the other site | part of the said fuel cell. It is front explanatory drawing of the 1st metal separator which comprises the said electric power generation cell. It is explanatory drawing of one surface of the 2nd metal separator which comprises the said electric power generation cell. It is explanatory drawing of the other surface of the 2nd metal separator which comprises the said electric power generation cell. It is principal part disassembled perspective explanatory drawing of the said electric power generation cell. It is a relationship explanatory drawing of the surface pressure and C direction position of this embodiment and a comparative example. 2 is an explanatory diagram of a PEM fuel cell of Patent Document 1. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Fuel cell 12 ... Power generation cell 16 ... Electrolyte membrane / electrode structure 18, 20 ... Metal separator 30a ... Oxidant gas inlet communication hole 30b ... Oxidant gas outlet communication hole 32a ... Cooling medium inlet communication hole 32b ... Cooling medium outlet Communication hole 34a ... Fuel gas inlet communication hole 34b ... Fuel gas outlet communication hole 36 ... Solid polymer electrolyte membrane 38 ... Anode side electrode 40 ... Cathode side electrode 42 ... Oxidant gas flow path 44 ... Fuel gas flow path 46 ... Cooling medium Flow path 50, 56 ... Seal member 52, 54 ... Flat part 58a, 58c ... Outer seal 58b, 58d ... Inner seal 60, 72, 84 ... Inlet connection part 62, 74, 86 ... Outlet connection part 64, 66, 76, 78, 88, 90, 100, 102 ... guide part 96 ... supply hole part 98 ... discharge hole part 104-118 ... molding part

Claims (4)

A power generation cell in which an electrolyte / electrode structure and a metal separator are disposed between a pair of electrodes is stacked, and a plurality of power generation cells are stacked to form a stack, and the electrolyte / electrode structure and the A reaction gas flow path for supplying a reaction gas along the electrode surface is provided between the metal separator, and a cooling medium flow path for supplying a cooling medium between the power generation cells between the power generation cells. A fuel cell stack provided with
The power generation cell is provided with a reaction gas communication hole penetrating in the stacking direction and communicating with the reaction gas channel,
In the metal separator, a fluid passage for guiding the reaction gas from the reaction gas communication hole to the reaction gas channel is formed between the metal separators or between the metal separator and the electrolyte / electrode structure. A plurality of rubber or resin guide parts are integrally molded,
The metal separator has a concave or convex metal forming portion that overlaps with a region in which the plurality of guide portions are provided in the stacking direction and integrally extends in the arrangement direction of the plurality of guide portions. Fuel cell stack. 2. The fuel cell stack according to claim 1, wherein the reaction gas flow path is provided on one surface of the metal separator, and the reaction gas communication hole includes a reaction gas introduction hole formed through the metal separator. Through the other side of the metal separator through the reaction gas flow path,
The fuel cell stack, wherein the plurality of guide portions for guiding the reaction gas from the reaction gas communication hole to the reaction gas introduction hole are provided on the other surface of the metal separator. According to claim 1 or 2 fuel cell stack according the previous SL plurality of guide portions, the fuel cell stack, characterized in that it is integrally molded to the metal separator via the recessed portion of the metal forming portions. The fuel cell stack according to any one of claims 1 to 3, wherein the power generation cell is provided with a cooling medium communication hole penetrating in the stacking direction and communicating with the cooling medium flow path.
The fuel cell stack, wherein the metal separator is provided with the plurality of guide portions for guiding the cooling medium from the cooling medium communication hole to the cooling medium flow path.

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