JP4548397B2 - Fuel cell - Google Patents

Description

  The present invention relates to a fuel cell, and more particularly to a fuel cell including a laminate in which a plurality of electrolyte layers and electrodes are laminated and a fuel flow path is formed inside.

  Conventionally, as this type of fuel cell, a fuel supply / discharge flow path is formed inside a laminated body constituting a fuel cell by laminating a plurality of single cells each having a through hole formed at a predetermined position. Have been proposed (for example, Japanese Patent Laid-Open Nos. 62-136777, 4-144069, and 5-174862).

  In these fuel cells, an electrolyte layer, a gas diffusion electrode sandwiched between the electrolyte layers and a sandwich structure, and a fuel flow path are formed between the gas diffusion electrodes sandwiched between the sandwich structures and adjacent unit cells. It is configured by stacking a plurality of unit cells each including a collecting electrode forming a partition wall. The fuel supply / discharge passage formed inside the fuel cell is formed by a through-hole penetrating the laminated surface formed at the outer edge of the collector electrode. As the material for forming the collector electrode, the collector electrode forms the fuel flow path and forms the partition wall of the unit cell, so it is chemically stable to the fuel, does not permeate the fuel, and has excellent conductivity. Is required. In the fuel cell described above, dense carbon (which is made to be gas-impermeable by compressing carbon) that satisfies these requirements is used.

  Further, in these fuel cells, in order to prevent the fuel from leaking from the fuel supply / discharge flow path, a seal member such as an O-ring is disposed on the outer periphery of the through hole formed in the outer edge portion of the collector electrode and stacked. is doing.

  However, in such a fuel cell in which a plurality of collector electrodes formed of dense carbon and formed with through holes for forming a fuel supply / discharge passage at the outer edge are laminated, the dense carbon is a brittle material. For this reason, there is a problem that cracks or the like are likely to occur due to impact or the like, and the fuel is likely to leak to the outside. In particular, when the fuel cell is mounted on a moving vehicle or the like, it is necessary to consider the impact caused by the accident of the moving vehicle or the like, and this problem is highlighted.

  Such a problem is not limited to the case where the collecting electrode is formed of dense carbon as a material, and the same is true when the collecting electrode is formed of another material.

  The fuel cell of the present invention has the following configuration in order to solve such problems and to prevent the fuel from leaking from the fuel supply / discharge passage formed in the fuel cell.

The fuel cell of the present invention comprises
A fuel cell comprising a laminate in which a plurality of unit cells each comprising an electrolyte layer and a gas diffusion electrode sandwiching the electrolyte layer are laminated,
A fuel flow path is formed along the stacking direction of the stack in the stack and in the periphery of the stack.
The gist is that the inner surface of the flow path is covered with a coating layer made of either rubber or resin or an adhesive mainly composed of rubber or resin over the stacking direction in the laminate. .

  In such a fuel cell, the laminated body may cover at least a part of the fuel flow path forming surface.

  Here, in the fuel cell, the coating layer may be formed of an insulating material.

  The fuel cell of the present invention configured as described above is laminated on the inner surface of the fuel flow path formed along the stacking direction of the stack inside the stack and at the periphery of the stack. A covering layer made of either rubber or resin or an adhesive mainly composed of rubber or resin is coated over the body in the laminating direction.

  In the fuel cell of the present invention, if the covering layer is made of an insulating material, it is possible to prevent short circuit between the single cells due to the covering layer, and when the fuel cell is mounted on a moving vehicle, etc. Insulation becomes easy.

  In order to further clarify the configuration and operation of the present invention described above, preferred embodiments of the present invention will be described below. FIG. 1 is an explanatory diagram showing an outline of the configuration of a laminate 10 constituting a fuel cell as an embodiment of the present invention, FIG. 2 is an exploded perspective view illustrating the configuration of a unit cell 11 constituting the laminate 10, and FIG. These are sectional drawings of the laminated body as a reference example.

As shown in FIG. 1 and FIG. 2, the laminate 10 includes an electrolyte membrane 12, two gas diffusion electrodes 14 sandwiching the electrolyte membrane 12 and having a sandwich structure, and sandwiching the sandwich structure and of adjacent single cells. Two collector electrodes 20 forming a partition wall and a plurality of seal members 40 sandwiched between the collector electrodes 20 together with a sandwich structure are laminated. End plates 50 are attached to both laminated ends of the laminated body 10, and coating layers 60 are formed on the entire surface on four side surfaces along the laminated direction of the laminated body 10.

The electrolyte membrane 12 is an ion exchange membrane having a thickness of 100 μm to 200 μm formed of a polymer material, for example, a fluororesin, and exhibits good electrical conductivity in a wet state. The two gas diffusion electrodes 14 are formed of carbon cloth woven with yarns in which carbon fibers whose surfaces are coated with polytetrafluoroethylene and carbon fibers that are not treated at all are in a ratio of 1: 1. Since the polytetrafluoroethylene exhibits water repellency, the surface of the gas diffusion electrode 14 is covered with water and does not hinder gas permeation. Carbon powder carrying platinum or an alloy composed of platinum and other metals as a catalyst is kneaded into the surface and gaps on the electrolyte membrane 12 side of the carbon cloth. The electrolyte membrane 12 and the two gas diffusion electrodes 14 are 1 MPa at a temperature of 100 ° C. to 160 ° C., preferably 110 ° C. to 130 ° C., with the two gas diffusion electrodes 14 sandwiching the electrolyte membrane 12. Joining is performed by a hot press method in which a pressure of {10.2 kgf / cm ² } to 20 MPa {102 kgf / cm ² }, preferably 5 MPa {51 kgf / cm ² } to 10 MPa {102 kgf / cm ² } is applied.

The collector electrode 20 is formed of dense carbon that is compressed and densified by compressing carbon. The collector electrode 20 is formed in a square thin plate shape, and two pairs of through-holes 22, 24 and 32, 34 which are long and parallel to the side are formed in the vicinity of the edge of each side. The two pairs of through-holes 22, 24, 32, and 34 are used to supply / discharge the oxidizing gas (gas containing oxygen such as air) that penetrates the stacked body in the stacking direction when the stacked body is formed. , 24a and fuel gas (gas containing hydrogen such as methanol reformed gas) supply / discharge passages 32a, 34a are formed. Between the pair of through holes 22 and 24 on the surface (display surface in FIG. 2) of the collector electrode 20 that is in contact with the gas diffusion electrode 14, a plurality of parallel electrodes arranged in the longitudinal direction of the pair of through holes 32 and 34 are provided. The rib 26 is formed. The rib 26 forms an oxidation gas passage 28 with the gas diffusion electrode 14. Further, between the pair of through holes 32 and 34 on the surface (the back surface in FIG. 2) of the collector electrode 20 that contacts the gas diffusion electrode 14, parallel to the longitudinal direction of the pair of through holes 22 and 24 (the rib 26 and A plurality of ribs 36 arranged in the (perpendicular direction) are formed. Similarly to the rib 26, the rib 36 forms a fuel gas passage 38 with the gas diffusion electrode 14.

  The end plate 50 is formed in a square plate shape with resin, and circular through holes 52 and 54 are formed in the center near the edges of two adjacent sides of the four sides. The through hole 52 of the left end plate 50 in FIG. 1 communicates with the oxidizing gas supply / discharge passage 22a formed in the laminate, and the through hole 54 communicates with the fuel gas supply / discharge passage 32a. ing. Although not shown, the through hole 52 of the right end plate 50 in FIG. 1 communicates with the oxidizing gas supply / discharge flow path 24a, and the through hole 54 communicates with the fuel gas supply / discharge flow path 34a. Yes.

  The covering layer 60 is formed of rubber (for example, nitrile rubber, styrene rubber, silicone rubber, fluorine rubber, polyacrylate rubber, ethylene propylene rubber, butyl rubber, urethane rubber, etc.) that is an insulating material. The coating layer 60 is formed by laminating a plurality of electrolyte membranes 12, gas diffusion electrodes 14, and collector electrodes 20 together with the seal member 40, and after attaching end plates 50 to both lamination ends, four side surfaces along the lamination direction of the laminate 10 are provided. It is formed by adhering and fixing a sheet-like rubber. As shown in FIG. 3, the covering layer 60 is formed so as to completely cover the side surface of the stacked body 10.

  An oxidant gas supply / discharge device (not shown) and a fuel gas supply / discharge device (not shown) for supplying and discharging oxidant gas and fuel gas are connected to the through holes 52 and 54 of the end plate 50 attached to both ends of the laminate 10 thus configured. If the oxidizing gas is supplied from one of the oxidizing gas supply / discharge passages 22a, 24a of the laminate 10 and the fuel gas is supplied from one of the fuel gas supply / discharge passages 32a, 34a, The oxidizing gas and the fuel gas are respectively supplied to the two gas diffusion electrodes 14 facing each other with the electrolyte membrane 12 interposed therebetween via the passage 28 and the fuel gas passage 38. The laminated body 10 has the following formulas (1) and (2). The chemical energy is directly converted into electric energy by the reaction shown in the following.

Cathode reaction (oxygen electrode): 2H ⁺ + 2e ⁻ + (1/2) O ₂ → H ₂ O (1)
Anode reaction (fuel electrode): H ₂ → 2H ⁺ + 2e ⁻ (2)

  According to the fuel cell as the reference example described above, the inside and outside of the laminate 10 can be blocked by the coating layer 60 formed of rubber. For this reason, even if an impact load acts on the laminated body 10 and a crack or the like occurs on the side surface of the laminated body 10 on which the coating layer 60 is formed, the oxidizing gas or the fuel gas is supplied to the oxidizing gas supply / discharge passage 22a, It is possible to prevent leakage from the flow path 32a or 34a for supplying or discharging fuel gas 24a or fuel gas. Moreover, since the coating layer 60 is formed of an insulating material, inconveniences such as a short circuit due to contact with other devices can be prevented, and the fuel cell can be easily handled.

  In this fuel cell, the coating layer 60 is formed of rubber. However, in the embodiments shown below, the resin (for example, epoxy-based, acrylic-urethane-based, silicon-based, etc.), rubber, or resin is the main component. A structure formed by an adhesive is also suitable. In the fuel cell of the example, the covering layer 60 is formed of an insulating material. However, when the outer peripheral portion of the collecting electrode 20 is formed of an insulating material, the covering layer 60 may be formed of a conductive material. Is possible. In this fuel cell, the coating layer 60 is formed by adhering and fixing a sheet-like rubber to the side surface of the laminate 10, but a coating is formed by applying or spraying a liquid polymer material mainly composed of rubber or resin. A configuration in which the coating layer 60 is formed and dried is also suitable.

  In this fuel cell, the coating layer 60 is formed so as to cover all four side surfaces of the stacked body 10, but the coating layer 60 is formed so as to cover the other end plates 50 of the four side surfaces of the stacked body 10. A configuration is also suitable. Moreover, the structure which forms the coating layer 60 only in two side surfaces of the laminated body 10 may be sufficient. This configuration is shown in FIGS. 4 is a perspective view of a laminated body 110 that is a modification of the laminated body 10, and FIG. 5 is a cross-sectional view of the laminated body 110 shown in FIG. 4 on a 5-5 plane (a laminated surface of the collector electrode 20). As shown in FIGS. 4 and 5, the laminated body 110 has the covering layer 160 formed only on two surfaces parallel to the longitudinal direction of the through holes 32 and 34 of the collector electrode 20. In the fuel cell having this configuration, even when an impact load acts on the laminate 110 and a crack or the like occurs on the side surface of the laminate 110 on which the coating layer 160 is formed, the coating layer 160 has a fuel gas supply / discharge passage. Since 32a, 34a is cut off from the outside, it is possible to prevent the fuel gas from leaking from the fuel gas supply / discharge passages 32a, 34a.

  In this fuel cell, the coating layer 60 is formed so as to cover the four side surfaces of the laminate 10 with one sheet-like rubber, but the coating layer 60 may be separated into two or more by a plurality of sheet-like rubbers. Good. For example, like the laminated body 210 shown in FIG. 6, a coating layer 260 is formed for each module including a plurality of unit cells 11, this module is laminated, and an end plate 50 is attached to the laminated end to form the laminated body 210. Also good. In this case, the number of unit cells 11 constituting the module may be any number.

  Next, a fuel cell which is an embodiment of the present invention will be described. FIG. 7 is a cross-sectional view showing a cross section (a cross section of the stack surface of the collector electrode 20) of the stack constituting the fuel cell of the example. The fuel cell of the second embodiment has the same configuration as the fuel cell of the reference example except for the location where the coating layer 60 is formed. Therefore, among the configurations of the fuel cell of the embodiment, the same reference numerals are given to the same configurations as those of the fuel cell of the reference example, and the description thereof is omitted.

As shown in the figure, in the fuel cell of the example, the through holes 22 and 24 of the collector electrode 20 are shown.
32, 34 are provided with a coating layer 360 formed of the same material as that of the coating layer 60 of the first embodiment on the surface on the edge side of the collector electrode 20 of the inner peripheral surfaces. The coating layer 360 is formed by laminating the electrolyte membrane 12, the gas diffusion electrode 14, the collector electrode 20, and the seal member 40, and before attaching the end plate 50 to both ends of the laminate, the through holes 22, 24, 32, A nozzle with a pipe is inserted inside the oxidizing gas supply / discharge passages 22a, 24a and the fuel gas supply / discharge passages 32a, 34a formed by 34, and liquid rubber is sprayed from the nozzles to supply / discharge flow. A film made of liquid rubber is formed inside the passages 22a, 24a, 32a, and 34a, and this is dried to form.

  According to the fuel cell of the embodiment described above, the coating layer 360 is formed on the edge side of the collecting electrode 20 inside the oxidizing gas supply / discharge channels 22a, 24a and the fuel gas supply / discharge channels 32a, 34a. As a result, even if an impact load acts on the laminated body and a crack or the like occurs at the edge or the like of the collector electrode 20 constituting the laminated body, the oxidizing gas or fuel gas is supplied to the oxidizing gas supply / discharge passages 22a and 24a. In addition, leakage from the fuel gas supply / discharge passages 32a and 34a can be prevented. Further, since the covering layer 360 is formed of an insulating material, the covering layer 360 does not cause a short circuit between the single cells. Therefore, the formation portions of the through holes 22, 24, 32, and 34 of the collector electrode 20 may be formed of any material, and the degree of design freedom can be increased.

  In the fuel cell of the embodiment, the coating layer 360 is formed in the oxidizing gas supply / discharge channels 22a, 24a and the fuel gas supply / discharge channels 32a, 34a. However, in the case where air is used as the oxidizing gas, the fuel gas is used. The coating layer 360 may be formed only in the supply / discharge channels 32a and 34a. With this configuration, the labor for forming the coating layer 360 is reduced as compared with the fuel cell of the embodiment, and the manufacturing process can be simplified. Further, in the fuel cell of the example, after the collector electrode 20 and the like were laminated, the nozzle with a tube was inserted and the liquid rubber was sprayed to form the coating layer 360. However, the coating layer 360 is covered for each module composed of a plurality of single cells. The layer 360 may be formed, and this module may be stacked to form a stacked body.

  The embodiments of the present invention have been described above. However, the present invention is not limited to these embodiments, and it is needless to say that the present invention can be implemented in various modes without departing from the gist of the present invention.

  According to the fuel cell described above, the coating layer made of an elastic body that covers at least a part of the side surface of the laminate over the plurality of single cells shuts off the laminate and the outside. Even if a crack or the like occurs, it is possible to prevent the fuel from leaking out from the crack or the like.

  In such a fuel cell, if the coating layer is made of an insulating material, a short circuit between the single cells due to the coating layer can be prevented. Therefore, the member forming the outer peripheral surface of the laminated body may be formed of any material, and the degree of design freedom can be increased. Also, when mounted on a moving vehicle, it can be easily insulated from other devices.

  According to the fuel cell of the present invention, the coating layer made of either rubber, resin, or rubber or resin-based adhesive covering at least part of the formation surface of the fuel channel is the fuel channel. Shut off inside and outside.

  In the fuel cell of the present invention, if the coating layer is made of an insulating material, a short circuit between members due to the coating layer can be prevented. Therefore, the member forming the fuel flow path may be formed of any material, and the degree of design freedom can be increased.

BRIEF DESCRIPTION OF THE DRAWINGS Explanatory drawing which shows the outline of a structure of the laminated body 10 which comprises the fuel cell which is a suitable one Example of this invention. FIG. 2 is an exploded perspective view illustrating the configuration of a single battery 11 that constitutes a stacked body 10. Sectional drawing of the laminated body 10 as a reference example. The perspective view of the laminated body 110 which is a modification of the laminated body 10 of a reference example. Sectional drawing of 5-5 plane of the laminated body 110 shown in FIG. The perspective view of the laminated body 210 which is a modification of the laminated body 10 of a reference example. Sectional drawing of the laminated body of the fuel cell of an Example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Laminated body 11 ... Single cell 12 ... Electrolyte membrane 14 ... Gas diffusion electrode 20 ... Collector electrode 22, 24, 32, 34 ... Through-hole 22a, 24a ... Supply / exhaust flow path of oxidizing gas 26 ... Rib 28 ... Passage 32a , 34a ... Fuel gas supply / discharge passage 36 ... Rib 38 ... Passage 40 ... Seal member 50 ... End plate 52, 54 ... Through hole 60 ... Cover layer 110 ... Laminate 160 ... Cover layer 210 ... Laminate 260 ... Cover Layer 360 ... coating layer

Claims (3)

A fuel cell comprising a laminate in which a plurality of unit cells each comprising an electrolyte layer and a gas diffusion electrode sandwiching the electrolyte layer are laminated,
A fuel flow path is formed along the stacking direction of the stack in the stack and in the periphery of the stack.
A fuel cell in which an inner surface of the flow path is coated with a coating layer made of either rubber or resin or an adhesive mainly composed of rubber or resin over the stacking direction in the stack. The fuel cell according to claim 1, wherein
The coating layer is a fuel cell formed of an insulating material. The fuel cell according to claim 1 or 2,
The said coating layer is a fuel cell formed for every module formed by laminating | stacking the module comprised by a several cell.

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