JP2021111578A - Fuel battery separator - Google Patents

Abstract

To provide a fuel battery separator that can improve conductivity.SOLUTION: A separator 3 is provided in a fuel battery cell that forms a cell stack of fuel cells by being stacked in a thickness direction, and a second layer 22 has a three-layer structure so as to be sandwiched in the thickness direction by a pair of first layers 21. The first layer 21 and the second layer 22 contain conductive fibers 23 and 26, respectively. The conductive fibers contained in the first layer 21 and the second layer 22 are brought into contact with each other at a large number of points, such that the conductivity is enhanced. Since such conductive fibers are included not only in the first layer 21 but also in the second layer 22, the conductivity of the separator 3 can be improved.SELECTED DRAWING: Figure 2

Description

The present invention relates to a fuel cell separator.

The cell stack of a fuel cell is formed by stacking fuel cell cells in the thickness direction thereof. Further, the fuel cell includes a sheet-shaped membrane electrode gas diffusion layer junction (MEGA: Membrane Electrode Gas-diffusion Assembly) and a pair of separators that sandwich the membrane electrode gas diffusion layer junction in the thickness direction. There is. The pair of separators in the fuel cell are for forming a flow path for supplying and discharging fuel gas (hydrogen and the like) and oxidation gas (air and the like) to the membrane electrode gas diffusion layer joint body. The pair of separators also function as a current collector for the fuel cell.

Of the pair of separators, one separator is located on the cathode side of the membrane electrode gas diffusion layer junction, and the other separator is located on the anode side of the membrane electrode gas diffusion layer junction. In the cell stack of a fuel cell, a fuel gas such as hydrogen flows between the other separator and the anode side of the membrane electrode gas diffusion layer junction, and at the same time, one separator and the cathode side of the membrane electrode gas diffusion layer conjugate Oxidizing gas such as air flows between and. Then, power generation in the fuel cell is performed based on the reaction of the fuel gas and the oxidation gas in the membrane electrode gas diffusion layer junction.

Patent Document 1 discloses a separator having a three-layer structure in which a second layer is sandwiched in the thickness direction by a pair of first layers. In this separator, the characteristics of the separator can be appropriately adjusted by individually selecting the material of each layer. Incidentally, in the separator of Patent Document 1, the first layer is assumed to contain conductive fibers, while the second layer is formed of an expanded graphite sheet.

The separator is required to have conductivity because it functions as a current collector of a fuel cell, and the above-mentioned conductive fibers and expanded graphite sheet are used to give the separator such conductivity. Further, since the separator forms a flow path for supplying and discharging fuel gas and oxidation gas to the membrane electrode gas diffusion layer joint body, gas sealing property is also required, and the separator is provided with such gas sealing property. Therefore, the above-mentioned expanded graphite sheet is used.

Japanese Unexamined Patent Publication No. 2001-15131

By the way, the expanded graphite sheet for forming the second layer of the separator has excellent performance in that the separator has gas sealability, but it is not necessarily at a sufficient level in that the separator has conductivity. It does not always reach. Therefore, in the separator of Patent Document 1, there is room for further improvement in terms of conductivity that affects the performance as a current collector.

An object of the present invention is to provide a fuel cell separator capable of improving conductivity.

Hereinafter, means for solving the above problems and their actions and effects will be described.
The separator that solves the above problems is provided in the fuel cell that forms the cell stack of the fuel cell by being laminated in the thickness direction, and the second layer is sandwiched by the first layer in the thickness direction. It has a three-layer structure. The first layer and the second layer each contain conductive fibers.

According to this configuration, in the first layer and the second layer of the separator, the conductive fibers are in contact with each other at a large number of points, so that the conductivity is enhanced. Since such conductive fibers are contained not only in the first layer but also in the second layer, the conductivity of the separator can be improved.

Sectional drawing which shows the cell stack of a fuel cell. Sectional drawing which shows the separator.

Hereinafter, an embodiment of the fuel cell separator will be described with reference to FIGS. 1 and 2.
As shown in FIG. 1, the cell stack of the fuel cell is formed by stacking the fuel cell 1 in the thickness direction thereof. The fuel cell 1 includes a sheet-shaped membrane electrode gas diffusion layer junction 2 and a pair of separators 3 that sandwich the membrane electrode gas diffusion layer junction 2 in the thickness direction.

The membrane electrode gas diffusion layer junction 2 includes, for example, an electrolyte layer 5 formed of a solid polymer membrane and a cathode electrode layer 6 bonded to one side (upper side of FIG. 1) of the electrolyte layer 5 in the thickness direction. The anode electrode layer 7 is joined to the other side (lower side in FIG. 1) of the electrolyte layer 5 in the thickness direction. Further, the surface of the cathode electrode layer 6 opposite to the electrolyte layer 5 is covered with the gas diffusion layer 8, and the surface of the anode electrode layer 7 opposite to the electrolyte layer 5 is covered with the gas diffusion layer 9.

Of the pair of separators 3, one separator 3 is located on the cathode side of the membrane electrode gas diffusion layer junction 2. A plurality of concave portions 11 and a plurality of convex portions 12 are formed on the separator 3 so as to be parallel and staggered, and the convex portions 12 are in contact with the gas diffusion layer 8 on the cathode electrode layer 6 side. Further, in the separator 3, the fuel cell cell is located inside the concave portion 11 located between the convex portions 12, that is, between the concave portion 11 and the gas diffusion layer 8 of the membrane electrode gas diffusion layer joint 2. A flow path 13 is formed in which the oxidizing gas flowing into the stack flows. The gas diffusion layer 8 is for efficiently guiding the oxidizing gas flowing in the flow path 13 to the cathode electrode layer 6, and is formed of a conductive non-woven fabric or the like. Then, the oxidizing gas that has passed through the flow path 13 flows out from the cell stack of the fuel cell.

Of the pair of separators 3, the other separator 3 is located on the anode side of the membrane electrode gas diffusion layer junction 2. A plurality of concave portions 14 and a plurality of convex portions 15 are formed on the separator 3 so as to be parallel and staggered, and the convex portions 15 are in contact with the gas diffusion layer 9 on the anode electrode layer 7 side. Further, in the separator 3, the fuel cell cell is located inside the concave portion 14 located between the convex portions 15, that is, between the concave portion 14 and the gas diffusion layer 9 of the membrane electrode gas diffusion layer joint 2. A flow path 16 for flowing the fuel gas flowing into the stack is formed. The gas diffusion layer 9 is for efficiently guiding the fuel gas flowing in the flow path 16 to the anode electrode layer 7, and is formed of a conductive non-woven fabric or the like. Then, the fuel gas that has passed through the flow path 16 flows out from the cell stack of the fuel cell.

In the fuel cell 1, when fuel gas is supplied to the anode electrode layer 7 of the membrane electrode gas diffusion layer junction 2 and oxidation gas is supplied to the cathode electrode layer 6 of the membrane electrode gas diffusion layer junction 2. Power is generated based on the reaction of the fuel gas and the oxide gas in the membrane electrode gas diffusion layer junction 2. In the fuel cell 1, the thermal expansion due to the heat generation occurs during power generation, while the thermal contraction due to cooling occurs when the power generation is stopped.

Next, the separator 3 will be described in detail.
As shown in FIG. 2, the separator 3 has a three-layer structure in which the second layer 22 is sandwiched by a pair of first layers 21 in the thickness direction.

The first layer 21 and the second layer 22 each contain conductive fibers. Incidentally, the length of the conductive fiber 23 contained in the first layer 21 and the length of the conductive fiber 26 contained in the second layer 22 are different from each other. In this example, the length of the conductive fibers 23 contained in the first layer 21 is shortened so as to be, for example, about one tenth of the length of the conductive fibers 26 contained in the second layer 22. ..

In addition to the conductive fibers 23, the first layer 21 also contains graphite powder 27. The first layer 21 is formed by using a thermoplastic resin 24 for binding the conductive fibers 23 to each other in a state of being in contact with each other, and an elastomer 25 for imparting toughness to the separator 3. .. Specifically, the first layer 21 is formed by subjecting a mixture of conductive fibers 23, thermoplastic resin 24, elastomer 25, and graphite powder 27 to hot pressing.

As the thermoplastic resin 24, polypropylene (PP), polyamide (PA), polyethylene naphthalate (PEN), or the like can be used. Further, as the elastomer 25, rubber or the like can be used.

On the other hand, the second layer 22 contains graphite powder 27 in addition to the conductive fibers 26. The second layer 22 is formed by subjecting a mixture of conductive fibers 26 to graphite powder 27 to hot press processing.

Then, the separator 3 is formed by stacking the first layer 21 on both the front and back surfaces of the second layer 22 formed in this manner in the thickness direction and performing heat pressing on them.

Next, the action and effect of the separator 3 in the present embodiment will be described.
(1) Conductive fibers are contained in the first layer 21 and the second layer 22 of the separator 3, respectively, and the conductive fibers 23 of the first layer 21 and the conductive fibers 26 of the second layer 22 are each other. It will be in contact with many places and the conductivity will be enhanced. Since the conductive fibers are contained not only in the first layer 21 but also in the second layer 22 as described above, the conductivity of the separator 3 can be improved.

(2) If the conductive fiber is lengthened, the toughness to cope with the same force when the force acts on the separator 3 is enhanced. On the other hand, if the conductive fibers are shortened, the number of places where the conductive fibers come into contact with each other increases, so that the conductivity of the separator 3 is enhanced. By adjusting the lengths of the conductive fibers 23 of the first layer 21 and the conductive fibers 26 of the second layer 22 to different values in consideration of the difference in characteristics due to the length of the conductive fibers, the separator is separated. The characteristics of the first layer 21 and the second layer 22 of No. 3 can be determined separately.

(3) The first layer 21 of the separator 3 is located on the outer surface side of the second layer 22, and the length of the conductive fibers 23 contained in the first layer 21 is set to the length of the conductive fibers contained in the second layer 22. By making the length shorter than the length of 26 and increasing the conductivity of the first layer 21, the electrical resistance of the separator 3 as a whole can be suppressed to a small value and the conductivity can be effectively increased. Further, if the length of the conductive fibers 23 contained in the first layer 21 is shortened, the conductive fibers 23 can be easily mixed with the thermoplastic resin 24 and the elastomer 25. On the other hand, since the length of the conductive fibers 26 contained in the second layer 22 is longer than the length of the conductive fibers 23 contained in the first layer 21, the toughness of the separator 3 can be increased. Therefore, when a force associated with thermal expansion and contraction of the fuel cell 1 acts on the separator 3, the force can be dealt with through the toughness of the separator 3.

(4) Since the first layer 21 contains the thermoplastic resin 24 for binding the conductive fibers 23 to each other in contact with each other, the first layer 21 is located on the outer surface side of the second layer 22 in the separator 3. The thermoplastic resin 24 can prevent the conductive fibers 23 from peeling off from the layer 21.

(5) By including the graphite powder 27 in the first layer 21 and the second layer 22, the conductive fibers can be efficiently and electrically connected to each other by the graphite powder 27, so that the conductivity of the separator 3 is conductive. The sex can be further enhanced.

The above embodiment can be changed as follows, for example. The above embodiment and the following modified examples can be implemented in combination with each other within a technically consistent range.
-The graphite powder 27 may be contained in only one of the first layer 21 and the second layer 22.

-It is not always necessary to include the graphite powder 27 in the first layer 21 and the second layer 22.
-The second layer 22 may contain a thermoplastic resin or an elastomer. In this case, the thermoplastic resin 24 and the elastomer 25 of the first layer 21 may be omitted.

-It is not always necessary that the length of the conductive fibers 23 contained in the first layer 21 be shorter than the length of the conductive fibers 26 contained in the second layer 22.
-The second layer 22 may include a mesh having conductivity. In this case, when the separator 3 is formed through hot press working, the thermoplastic resin 24 contained in the first layer 21 penetrates into the mesh of the second layer 22, whereby the second layer 22 and the first layer 21 are brought into close contact with each other. The degree becomes high. As a result, the conductivity of the separator 3 can be further enhanced.

The second layer 22 may include a non-woven fabric having the same conductivity as the non-woven fabric forming the gas diffusion layers 8 and 9. In this case, when the separator 3 is formed through hot press working, the thermoplastic resin 24 contained in the first layer 21 penetrates into the non-woven fabric of the second layer 22, whereby the second layer 22 and the first layer 21 are brought into close contact with each other. The degree becomes high. As a result, the conductivity of the separator 3 can be further enhanced.

1 ... Fuel cell 2 ... Film electrode gas diffusion layer Bonded body 3 ... Separator 5 ... Electrolyte layer 6 ... Cathode electrode layer 7 ... Anode electrode layer 8 ... Gas diffusion layer 9 ... Gas diffusion layer 11 ... Concave portion 12 ... Convex portion 13 ... Flow path 14 ... Concave portion 15 ... Convex portion 16 ... Flow path 21 ... First layer 22 ... Second layer 23 ... Conductive fiber 24 ... Thermoplastic resin 25 ... Elastoma 26 ... Conductive fiber 27 ... Graphite powder

Claims (5)

It is provided in a fuel cell that forms a cell stack of a fuel cell by being laminated in the thickness direction, and has a three-layer structure in which a second layer is sandwiched in the thickness direction by a first layer. And
A fuel cell separator, wherein each of the first layer and the second layer contains conductive fibers. The fuel cell separator according to claim 1, wherein the length of the conductive fiber contained in the first layer is different from the length of the conductive fiber contained in the second layer. The fuel cell separator according to claim 2, wherein the length of the conductive fibers contained in the first layer is shorter than the length of the conductive fibers contained in the second layer. The fuel cell separator according to claim 3, wherein the first layer contains a thermoplastic resin for bonding conductive fibers in contact with each other. The fuel cell separator according to any one of claims 1 to 4, wherein graphite powder is contained in at least one of the first layer and the second layer.

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