JP4109569B2 - Fuel cell - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
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 the power generation cell penetrates in the stacking direction and communicates with a reaction gas flow path. The present invention relates to an internal manifold type fuel cell provided with a reaction gas communication hole and a cooling medium communication hole communicating with a cooling medium flow path.
[0002]
[Prior art]
For example, a polymer electrolyte fuel cell has an electrolyte / electrode structure in which an anode electrode and a cathode electrode are respectively provided on both sides of an electrolyte (electrolyte membrane) made of a polymer ion exchange membrane (cation exchange membrane). A power generation cell sandwiched between separators is provided. This type of fuel cell is normally used as a fuel cell stack by stacking a predetermined number of power generation cells.
[0003]
In this power generation cell, the fuel gas supplied to the anode side electrode, for example, a gas mainly containing hydrogen (hereinafter also referred to as a hydrogen-containing gas) is ionized with hydrogen on the electrode catalyst, and the cathode side passes through the electrolyte. Move to the electrode side. Electrons generated during that time are taken out to an external circuit and used as direct current electric energy. The cathode side electrode is supplied with an oxidant gas, for example, a gas mainly containing oxygen or air (hereinafter also referred to as an oxygen-containing gas). And oxygen react to produce water.
[0004]
In the power generation cell, a reaction gas channel for flowing a reaction gas is provided in the plane of the separator so as to face each electrode, and the power generation cell is cooled between separators constituting adjacent power generation cells. A cooling medium flow path for flowing the cooling medium is provided. The reactive gas is an oxidant gas and a fuel gas, and the reactive gas flow path is an oxidant gas flow path for flowing the oxidant gas facing the cathode side electrode, and a fuel gas facing the anode side electrode. And a fuel gas flow path for flowing gas.
[0005]
On the other hand, at the peripheral edge of the separator, a fuel gas supply communication hole and a fuel gas discharge communication hole, which are reaction gas communication holes that penetrate the separator in the stacking direction 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.
[0006]
For example, the reaction gas channel and the reaction gas communication hole communicate with each other via a connection channel having parallel grooves or the like in order to flow the reaction gas smoothly and evenly. However, when the separator and the electrolyte / electrode structure are clamped and fixed with a seal member interposed therebetween, the seal member enters the connecting flow path, and the desired sealing performance cannot be maintained. In addition, there is a problem that the reaction gas does not flow well.
[0007]
Therefore, in the polymer electrolyte fuel cell stack disclosed in Patent Document 1, as shown in FIG. 7, a meandering reaction gas, for example, an oxidant gas flow path 2 is formed in the plane of the separator 1. . The oxidant gas flow channel 2 communicates with an oxidant gas supply through hole 3 and an oxidant gas discharge through hole 4 that penetrate the peripheral edge of the separator 1 in the stacking direction. The separator 1 is provided with a packing 5, which communicates the through holes 3 and 4 and the oxidant gas flow path 2 within the surface of the separator 1 and seals other through holes from these.
[0008]
In the connection flow paths 6a and 6b that connect the through holes 3 and 4 and the oxidant gas flow path 2, a SUS plate 7 that is a seal member is disposed so as to cover the connection flow paths 6a and 6b. The SUS plate 7 is configured in a rectangular shape, and ears 7a and 7b are provided at two locations, respectively, and the ears 7a and 7b are fitted to a stepped part 8 formed in the separator 1. .
[0009]
Thus, in Patent Document 1, since the SUS plate 7 covers the connection flow paths 6a and 6b, the polymer film (not shown) and the packing 5 do not fall into the oxidant gas flow path 2, The desired sealing performance can be ensured, and an increase in the pressure loss of the reaction gas can be prevented.
[0010]
[Patent Document 1]
JP 2001-266911 A (paragraphs [0026] to [0028], FIG. 1)
[0011]
[Problems to be solved by the invention]
However, in Patent Document 1 described above, the SUS plate 7 is attached to each of the connection flow paths 6a and 6b of the separator 1, and the attaching operation of the SUS plate 7 is complicated. In particular, when several tens to several hundreds of power generation cells are stacked, there is a problem that the mounting operation of the SUS plate 7 becomes more complicated and time-consuming, and the cost is significantly increased.
[0012]
Moreover, since the SUS plate 7 is mounted so as to cover the connection flow paths 6a and 6b, the dimensions of the connection flow paths 6a and 6b cannot be set smaller than the width dimension of the SUS plate 7. Accordingly, the area ratio of the electrode portion is reduced, and it is difficult to reduce the size and weight of the entire fuel cell.
[0013]
The present invention solves this kind of problem, and the assembly process of the fuel cell is effectively simplified, and desired sealing performance and power generation performance can be secured with an economical and compact configuration. An object is to provide a fuel cell.
[0014]
[Means for Solving the Problems]
The fuel cell according to claim 1 of 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 the electrolyte / electrode structure and the metal separator, In addition, a reaction gas flow path for supplying a reaction gas along the electrode surface is formed, and a cooling medium flow path for supplying a cooling medium is formed between the power generation cells. A reaction gas communication hole penetrating in the stacking direction and communicating with the reaction gas flow channel and a cooling medium communication hole communicating with the cooling medium flow channel are provided.
[0015]
A first seal is integrated on both surfaces of one metal separator so as to cover the outer peripheral edge, and a second seal is integrated on both surfaces of the other metal separator so as to cover the outer peripheral edge. State The first seal, while constituting a flat seal, a second seal constitutes the ridge seal, at least the first or second seal, the first and second seal are in contact with each other in the flow path for communicating the reactive gas flow channel and the reactant gas passage (hereinafter, also referred to as flow path functional unit) more convex receiving portion for configuring is found integrally provided.
[0016]
The flow path is a flow path formed by the first and second seal are in contact, for example, between the flat seal and the projecting seal, between the projecting seal and projecting seal, the flat seal It is formed between a circular or rectangular boss, or between a boss and a boss.
[0017]
Therefore, since the first and second seals themselves constitute a flow path that connects the reaction gas flow path and the reaction gas communication hole, a dedicated metal plate (for example, a SUS plate) or the like is not necessary. As a result, the mounting process of the metal plate or the like is reduced, the assembly process of the fuel cell is greatly simplified, and a desired sealing function can be ensured. Furthermore, it is possible to reduce the size of the flow path as much as possible, it is possible to increase the electrode area percentage of the power generation cell surface, the power generation performance of the fuel cell is easily efficiency.
[0018]
Further , the flow path includes a plurality of convex receiving portions provided integrally with at least the first or second seal, corresponding to the communication portion between the reaction gas flow path and the reaction gas communication hole. For this reason, desired sealing performance and power generation performance can be secured with an economical and simple configuration. Moreover, the convex receiving portion can have a backing function for maintaining the surface pressure necessary for the sealing function of the other seal.
[0021]
Further, the electrodeposition Kaishitsu electrode assembly, with sandwiching an electrolyte membrane in the first and second electrodes is set to a smaller surface area than the first electrode and the second electrode, so-called, step MEA is configured.
[0022]
The first seal is provided with an inner seal disposed between the electrolyte membrane and the separator and an outer seal disposed between adjacent separators. On the other hand, the second seal, Ru provided an inner seal which corresponds to the inner seal of the first seal and an outer seal which corresponds to the outer seal of the first seal. Thereby, while improving the intensity | strength of a power generation cell, the said power generation cell itself can be reduced in thickness.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
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 of a plurality of power generation cells 12 stacked in the direction of arrow A. 2 is a cross-sectional explanatory view of a main part of a fuel cell 10 made.
[0024]
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 14a and 14b 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.
[0025]
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 of For example, it is set within a range of 0.05 mm to 1.0 mm.
[0026]
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, eg, 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 arrow C direction (vertical direction). Are provided in an array.
[0027]
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 an oxidant gas outlet communication hole 30b for discharging the oxidant gas are arranged in the direction of arrow C.
[0028]
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.
[0029]
The anode side electrode 38 and the cathode side electrode 40 include 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.
[0030]
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.
[0031]
As shown in FIGS. 1 and 6, the surface 18b of the first metal separator 18 and the surface 20b of the second metal separator 20 communicate with the cooling medium inlet communication hole 32a and the cooling medium outlet communication hole 32b. A cooling medium flow path 46 is formed. The cooling medium flow path 46 extends linearly in the direction of arrow B.
[0032]
As shown in FIGS. 1 and 4, a first seal member (first seal) 50 is integrated with the surfaces 18 a and 18 b of the first metal separator 18 around the outer peripheral edge of the first metal separator 18. It becomes. 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.
[0033]
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. The second plane part 54 is configured to be longer than the first plane part 52.
[0034]
As shown in FIG. 2, the first flat portion 52 circulates at a position spaced outside from the outer peripheral end of the electrolyte membrane / electrode structure 16, while the second flat portion 54 has a predetermined contact with the cathode side electrode 40. Circulate the position where polymerization occurs over a range. 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.
[0035]
As shown in FIG. 5, a second seal member (second seal) 56 is integrated with the surfaces 20 a and 20 b of the second metal separator 20 around the outer peripheral edge of the second metal separator 20. . The second seal member 56 includes an outer seal 58a provided on the surface 20a in the vicinity of the outer peripheral end of the second metal separator 20, and is separated from the outer seal 58a by a predetermined distance to the inner seal 58b. Is provided.
[0036]
The outer seal 58a and the inner seal 58b can be selected from various shapes such as a tapered tip shape (lip shape), a trapezoidal shape, or a bowl shape. The outer seal 58a contacts the first flat portion 52 provided in 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. (See FIG. 2).
[0037]
As shown in FIG. 5, the outer seal 58a includes the oxidant gas inlet communication hole 30a, the cooling medium outlet communication hole 32b, the fuel gas outlet communication hole 34b, the fuel gas inlet communication hole 34a, the cooling medium inlet communication hole 32a, and the 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.
[0038]
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). The outer seal 58c and the inner seal 58d have the same shape as the outer seal 58a and the inner seal 58b described above.
[0039]
As shown in FIG. 5, the outer seal 58a includes an inlet channel function part 60 that allows the oxidant gas inlet communication hole 30a and the oxidant gas channel 42 to communicate with each other, the oxidant gas outlet communication hole 30b, and the oxidant gas. An outlet channel function part 62 that communicates with the channel 42 is provided.
[0040]
The inlet flow path function unit 60 includes a plurality of convex receiving portions 64 that intermittently cut out the outer seal 58a along the arrow C direction and that extends in the arrow B direction. The receiving portion 64 is a first plane. A communication path for the oxidant gas is formed between the receiving parts 64 in contact with the part 52 (see FIG. 3). Similarly, the outlet flow path function part 62 is provided with a plurality of convex receiving parts 66 extending in the direction of arrow B while partially cutting out the outer seal 58a. The receiving part 66 is in contact with the first flat surface part 52, and a communication path for oxidizing gas is formed between the receiving parts 66.
[0041]
The receiving part 64 of the inlet channel function part 60 and the seal overlapping part 68 of the outer seal 58c overlap each other on both surfaces 20a, 20b of the second metal separator 20. The seal overlapping portion 68 refers to a part of the outer seal 58c that overlaps the receiving portion 64 of the outer seal 58a with the second metal separator 20 interposed therebetween. The receiving part 64 extends in a direction intersecting with the seal overlapping part 68 and is longer than the width dimension of the seal overlapping part 68. The receiving part 64 and the seal overlapping part 68 are laminated. The amount of seal deformation in the stacking direction is set to be substantially the same with respect to the load in the direction.
[0042]
The outlet channel function part 62 is configured in the same manner as the inlet channel function part 60 described above, and each receiving part 66 and the seal overlap part 70 of the outer seal 58c that overlap each other on both surfaces 20a and 20b of the second metal separator 20 are arranged. The seal deformation amount in the stacking direction is set to be substantially the same with respect to the load in the stacking direction (see FIG. 5).
[0043]
As shown in FIG. 6, on the surface 20b of the second metal separator 20, an inlet channel functioning portion 72 that communicates the cooling medium inlet communication hole 32a and the cooling medium channel 46, the cooling medium outlet communication hole 32b, and the aforementioned An outlet channel function part 74 that communicates with the cooling medium channel 46 is provided. The inlet flow path function unit 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 receiving portions 76 extending in the direction of arrow B.
[0044]
Similarly, the outlet flow path functional unit 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 receiving portions 78 extending in the direction of arrow B. The receiving portions 76 and 78 are in contact with the second flat surface portion 54, and a communication path for the cooling medium is formed between the receiving portions 76 and 78.
[0045]
The inlet channel function part 72 overlaps the seal overlapping parts 80a and 80b constituting the outer seal 58a and the inner seal 58b of the surface 20a with the second metal separator 20 interposed therebetween. The receiving portions 76 and the seal overlapping portions 80a and 80b constituting the inlet flow path function unit 72 are set to have substantially the same seal deformation amount in the stacking direction with respect to the load in the stacking direction.
[0046]
Similarly, each receiving part 78 constituting the outlet channel function part 74 overlaps with the seal overlap portions 82a and 82b of the outer seal 58a and the inner seal 58b on both surfaces 20a and 20b of the second metal separator 20. The receiving portion 78 and the seal overlapping portions 82a and 82b are set to have substantially the same amount of seal deformation in the stacking direction with respect to the load in the stacking direction.
[0047]
As shown in FIG. 6, on the surface 20b, an inlet flow path functional part 84 and an outlet flow path functional part 86 are provided in the vicinity of the fuel gas inlet communication hole 34a and the fuel gas outlet communication hole 34b. The inlet channel function part 84 is provided with a plurality of convex receiving parts 88 arranged in the direction of the arrow C, while the outlet channel function part 86 is similarly provided with a plurality of convex receiving parts 90 arranged in the direction of the arrow C. Is provided. The receiving portions 88 and 90 are in contact with the second flat surface portion 54, and a communication path for fuel gas is formed between the receiving portions 88 and 90.
[0048]
Each receiving portion 88 overlaps with the seal overlapping portions 92a and 92b of the outer seal 58a and the inner seal 58b with the second metal separator 20 in between. Similarly, each receiving portion 90 overlaps the seal overlapping portions 94a and 94b of the outer seal 58a and the inner seal 58b with the second metal separator 20 interposed therebetween.
[0049]
The inlet flow path function unit 84 and the seal overlapping portions 92a and 92b, and the outlet flow path function portion 86 and the seal overlapping portions 94a and 94b are set to have substantially the same amount of seal deformation in the stacking direction with respect to the load in the stacking direction. Specifically, it has a configuration similar to that of the inlet flow path function unit 72. A plurality of supply hole portions 96 and discharge hole portions 98 are formed in the vicinity of the inlet flow path function portion 84 and the outlet flow path function portion 86, respectively, outside the inner seal 58d. The supply hole 96 and the discharge hole 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 (see FIG. 5). .
[0050]
The operation of the fuel cell 10 configured as described above will be described below.
[0051]
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, ethylene glycol, or oil is supplied to the cooling medium inlet communication hole 32a.
[0052]
For this reason, the oxidant gas is introduced into the oxidant gas flow path 42 of the first metal separator 18 from the oxidant gas inlet communication hole 30a (see FIG. 3), and moves vertically upward while meandering in the arrow B direction. And supplied to the cathode side electrode 40 constituting the electrolyte membrane / electrode structure 16. On the other hand, the fuel gas is introduced into the fuel gas flow path 44 of the second metal separator 20 from the fuel gas inlet communication hole 34a through the supply hole portion 96 (see FIG. 2), and vertically upward while meandering in the direction of arrow B. To the anode side electrode 38 constituting the electrolyte membrane / electrode structure 16.
[0053]
Accordingly, in each electrolyte membrane / electrode structure 16, the oxidant gas supplied to the cathode side electrode 40 and the fuel gas supplied to the anode side electrode 38 are consumed by an electrochemical reaction in the electrode catalyst layer. Power generation is performed.
[0054]
Next, the consumed fuel gas supplied to the anode side electrode 38 passes through the discharge hole portion 98 and is discharged in the direction of arrow A along the fuel gas outlet communication hole 34b. Similarly, the oxidant gas supplied to and consumed by the cathode side electrode 40 is discharged in the direction of arrow A along the oxidant gas outlet communication hole 30b.
[0055]
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, and then flows in the direction of arrow B. The cooling medium is discharged from the cooling medium outlet communication hole 32b after the electrolyte membrane / electrode structure 16 is cooled.
[0056]
In this case, in this embodiment, in order to supply the oxidant gas from the oxidant gas inlet communication hole 30a to the oxidant gas flow path 42, the surface 20a of the second metal separator 20 is provided with the inlet flow path function unit 60. A plurality of receiving parts 64 are provided. The receiving portion 64 constitutes a part of the outer seal 58a. As shown in FIG. 3, the receiving portion 64 contacts the first flat surface portion 52 provided on the surface 18a of the first metal separator 18. Thus, a communication path for the oxidant gas is formed between the receiving portions 66.
[0057]
For this reason, the inlet flow path functional unit 60 is constituted by a part of the second seal member 56 (receiving part 64) and a part of the first seal member 50 (first flat part 52). It is not necessary to use a dedicated metal plate such as a conventional SUS plate in order to cover the road function unit 60, and the mounting process of the metal plate is reduced. Therefore, the assembly process of the fuel cell 10 is greatly simplified, and the desired sealing function can be secured with an economical and simple configuration.
[0058]
Furthermore, the dimension of the inlet flow path function unit 60 can be made as small as possible, and the electrode area ratio in the surface of the power generation cell 12 can be increased, so that the power generation performance of the fuel cell 10 is easy. To be efficient.
[0059]
Furthermore, the inlet flow path function unit 60 includes a plurality of receiving portions 64 provided integrally with the second seal member 56. Thereby, the power generation cell 12 can ensure desired sealing performance and power generation performance with an economical and simple configuration. In addition, the receiving portion 64 has a backing function for maintaining a surface pressure necessary for the sealing function of the seal overlapping portion 68 constituting the outer seal 58a.
[0060]
The outlet channel function unit 62 also has the same effect as the inlet channel function unit 60 described above. Further, the same effect can be obtained in the inlet flow path function units 72 and 84 and the outlet flow path function parts 74 and 86.
[0061]
Thereby, in this embodiment, while stabilizing the power generation performance of the fuel cell 10, the flow rates of the fuel gas, the oxidant gas, and the cooling medium are uniformized with a simple configuration, and the power generation performance for each power generation cell 12 is achieved. It is possible to obtain an effect that the homogenization and stabilization are reliably achieved.
[0062]
In addition, the inlet flow path function unit 60 is a flow path formed by the first and second seal members 50 and 56 coming into contact with each other, for example, between a flat seal and a convex seal, and between a convex seal and a convex seal. May be formed between the flat seal, the flat seal and the circular or rectangular boss, or between the boss and the boss.
[0063]
【The invention's effect】
In the fuel cell according to the present invention, since the first and second seals themselves constitute a flow path that connects the reaction gas flow path and the reaction gas communication hole, a dedicated metal plate (for example, a SUS plate) or the like is unnecessary. Become.
[0064]
As a result, the mounting process of the metal plate or the like is reduced, the assembly process of the fuel cell is greatly simplified, and a desired sealing function can be ensured. Furthermore, it is possible to reduce the size of the flow path as much as possible, it is possible to increase the electrode area percentage of the power generation cell surface, the power generation performance of the fuel cell is easily efficiency.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view of a main part of a power generation cell constituting a fuel cell according to an embodiment of the present invention.
FIG. 2 is a cross-sectional explanatory view of a main part of the fuel cell.
FIG. 3 is an explanatory cross-sectional view of a main part of another part of the fuel cell.
FIG. 4 is a front explanatory view of a first metal separator constituting the power generation cell.
FIG. 5 is a front explanatory view of one surface of a second metal separator constituting the power generation cell.
FIG. 6 is a front explanatory view of the other surface of the second metal separator constituting the power generation cell.
7 is an explanatory diagram of a seal structure disclosed in 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 channel 44 ... Fuel gas channel 46 ... Cooling medium Flow paths 50, 56 ... Seal members 52, 54 ... Planar portions 58a, 58c ... Outer seals 58b, 58d ... Inner seals 60, 72, 84 ... Inlet flow function 62, 74, 86 ... Outlet flow functions 64, 66, 76, 78, 88, 90 ... receiving portions 68, 70, 80a, 80b, 82a, 82b, 92a, 92b, 94a, 94b ... seal overlapping portion 96 ... supply hole portion 8 ... discharge holes

Claims (3)

A power generation cell in which an electrolyte / electrode structure and a pair of metal separators, each having an electrolyte disposed between a pair of electrodes, are stacked, and reacts along the electrode surface between the electrolyte / electrode structure and the metal separator. A reaction gas flow path for supplying a gas is formed, and a cooling medium flow path for supplying a cooling medium is formed between the power generation cells. The reaction gas flow passes through the power generation cell in the stacking direction. An internal manifold type fuel cell provided with a reaction gas communication hole communicating with a passage and a cooling medium communication hole communicating with the cooling medium flow path,
A first seal is integrated on both surfaces of one metal separator to cover the outer peripheral edge, and a second seal is integrated on both surfaces of the other metal separator to cover the outer peripheral edge.
The first seal constitutes a flat seal, while the second seal constitutes a convex seal,
At least wherein the first or second seal, with the first and second seal are in contact with each other, the reaction gas flow path and the reactant gas passage and a plurality of for configuring a flow path for communicating fuel cell convex receiving portions is equal to or is found integrally provided. A fuel cell according to claim 1 Symbol placement, the electrolyte electrode structure sets the electrolyte membrane while sandwiched by the first and second electrodes, the first smaller surface area than the electrode the second electrode Has been
The first seal includes an inner seal disposed between the electrolyte membrane and the separator;
An outer seal disposed between adjacent separators;
A fuel cell comprising: The fuel cell according to claim 2 , wherein the second seal includes an inner seal corresponding to the inner seal of the first seal;
An outer side seal corresponding to the outer seal of the first seal,
A fuel cell comprising:

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