JP5596277B2 - Membrane electrode assembly and fuel cell - Google Patents

Description

  The present invention relates to a membrane electrode assembly and a fuel cell using the same.

  A solid polymer fuel cell is known as one form of the fuel cell. Solid polymer fuel cells have lower operating temperatures (about -30 ° C to 100 ° C) compared to other types of fuel cells, are low in cost, and can be made compact. ing.

  As shown in FIG. 4, the polymer electrolyte fuel cell has a membrane electrode assembly (MEA) 4 as a main component, and is sandwiched between separators 6 and 6 each having a gas flow path 5 to provide a single unit. One fuel cell A called a cell is formed. The membrane electrode assembly 4 has a structure in which catalyst layers 2 and 2 and gas diffusion layers 3 and 3 on the anode side and the cathode side are laminated on both surfaces of a solid polymer electrolyte membrane 1 which is an ion exchange membrane. The catalyst layer 2 is formed of a catalyst mixture containing at least an electroconductive carrier carrying catalyst particles and an electrolyte. Platinum-based metals are mainly used for the catalyst, and carbon particles are mainly used for the conductive carrier supporting the catalyst. For the gas diffusion layer 3, carbon paper or carbon cloth is mainly used.

  In the polymer electrolyte fuel cell, power generation proceeds as follows. First, hydrogen contained in the fuel gas supplied to the anode side is oxidized by the catalyst particles to become protons and electrons. Next, the generated protons pass through the electrolyte contained in the anode catalyst layer and the electrolyte membrane in contact with the catalyst layer, and reach the cathode catalyst layer. The electrons generated in the anode catalyst layer reach the cathode catalyst layer through the conductive carrier constituting the catalyst layer, the gas diffusion layer in contact with the catalyst layer, the separator, and the external circuit. The protons and electrons that have reached the cathode catalyst layer react with oxygen contained in an oxidant gas (for example, air) supplied to the cathode side to generate water.

  In order to obtain a fuel cell capable of maintaining high power generation performance over a long period of time, many technical improvements have been proposed, and one of them is a technical improvement related to the catalyst layer constituting the membrane electrode assembly. For example, the catalyst particles carried by the conductive carrier are alloyed, or the catalyst particles are atomized to increase the electrode reaction area of the catalyst to obtain a high catalyst activity. There is a problem in that the durability of the resin deteriorates. Although the durability of the catalyst layer can be improved by increasing the particle size of the catalyst particles or using highly crystallized catalyst-supported carbon, there is a trade-off between the performances. Thus, since the performance and durability of the catalyst layer are in a contradictory relationship, it has been proposed that the catalyst layer has a two-layer structure instead of a single-layer structure.

  For example, in Patent Document 1, the catalyst layer has a two-layer structure of a catalyst layer in which platinum particles are supported on a conductive carrier and a catalyst layer in which platinum alloy particles are supported on a conductive carrier. It has been proposed that a catalyst layer on which is supported is laminated on the electrolyte membrane side. Patent Document 2 discloses that the cathode side catalyst layer has a two-layer structure of a catalyst layer (I) on the electrolyte membrane side and a catalyst layer (II) on the gas diffusion layer side, and is included in the electrolyte membrane side catalyst layer (I). It has been proposed to make the average particle diameter (D1) of the catalyst particles larger than the average particle diameter (D2) of the catalyst particles contained in the gas diffusion layer side catalyst layer (II). It is described that the catalyst layer having such a two-layer structure can provide a catalyst layer for a membrane electrode assembly that can maintain desired power generation performance over a long period of time and has excellent durability.

JP 2006-79840 A JP 2006-79917 A

  The present inventors have continued many experiments and researches on fuel cells, membrane electrode assemblies, etc., and the catalyst layer is suitable for each by having a two-layer structure as described above. Although it becomes possible to place the catalyst layer in a limited area and a catalyst layer having both durability and high performance is obtained, for example, in a membrane electrode assembly using such a two-layer catalyst layer, When the thickness was 10 μm or less, it was experienced that drainage capacity was insufficient under high humidification conditions, and performance degradation due to flatting occurred. We also experienced that when the thickness of the entire catalyst layer was increased to solve this problem, dry-up occurred under low humidification conditions. Further, when the thickness of the catalyst layer is increased, there is a problem that the cost increases due to an increase in the amount of the catalyst.

  The present invention has been made in view of the above circumstances, and in a membrane electrode assembly for a fuel cell, it is possible to avoid occurrence of flatting by improving drainage as well as durability and high performance. It is an object of the present invention to disclose a membrane electrode assembly having a catalyst layer structure that can be operated under a wide range of operating conditions, and a fuel cell using the membrane electrode assembly.

  In the membrane electrode assembly according to the present invention, a cathode-side catalyst layer and an anode-side catalyst layer containing at least an electroconductive carrier carrying catalyst particles and an electrolyte are arranged to face both surfaces of the electrolyte membrane, and gas diffusion is performed in each catalyst layer. In the membrane electrode assembly for a fuel cell in which layers are laminated, at least the cathode side catalyst layer has a three-layer structure and the total thickness is 10 to 30 μm, and the first layer in contact with the electrolyte membrane is The thickness is 1 to 3 μm and it is a highly durable layer compared to the other two layers, and the second layer, which is an intermediate layer, is 3 to 9 μm in thickness and compared to the other two layers. The third layer in contact with the gas diffusion layer is a layer having a lower catalyst density or no catalyst compared to the other two layers.

  According to the experiments by the present inventors, during the power generation reaction of the fuel cell, in the area within the thickness of 1 to 3 μm from the electrolyte membrane in the catalyst layer, the load related to the catalyst particles is compared with the area outside it. The catalyst is likely to deteriorate in that area. Further, the catalyst particles function as a catalyst mostly within the thickness of 1 to 12 μm from the electrolyte membrane in the catalyst layer, and the power generation performance is affected by the catalyst particles existing in the area outside the catalyst layer. There is hardly anything. On the other hand, when the thickness of the catalyst layer is thinner than about 12 μm, the drainage capacity is insufficient under high humidification conditions, and the performance is deteriorated due to the flatting.

  At least the cathode side catalyst layer according to the present invention has a three-layer structure, and the first layer in contact with the electrolyte membrane has a thickness of 1 to 3 μm and is a highly durable layer compared to the other two layers. Therefore, high durability as the whole catalyst layer can be secured. A 2nd layer is 3-9 micrometers, and the sum of the thickness of a 1st layer and a 2nd layer is 4-12 micrometers. And the 2nd layer is made into the layer excellent in catalyst activity compared with other 2 layers, and can ensure the high electric power generation performance as a membrane electrode assembly. The third layer is a layer having a lower catalyst density or no catalyst compared to the other two layers. Thereby, the desired drainage property as a catalyst layer can be ensured, and it is also possible to avoid the deterioration of performance due to flotation under high humidification conditions. Moreover, the third layer does not have to be expected to have the power generation performance itself. For this reason, the third layer has a lower catalyst density or no catalyst compared to the other two layers. Therefore, the amount of expensive catalyst used is not increased, and the manufacturing cost of the catalyst layer is not increased.

  As described above, according to the present invention, since the catalyst layer has a three-layer structure, in addition to durability and high power generation efficiency, a membrane electrode capable of operating under a wide range of operating conditions by avoiding a flatting phenomenon. A joined body and a fuel cell using the same are obtained.

  FIG. 1 is a schematic view showing a part of a membrane electrode assembly according to the present invention. In FIG. 1, 10 is an electrolyte membrane, and 20 is a catalyst layer on the cathode side.

  The electrolyte membrane 10 is not particularly limited. For example, perfluorosulfonic acid membranes represented by various Nafion (registered trademark of DuPont) and Flemion (registered trademark of Asahi Glass) manufactured by DuPont, and ion exchange manufactured by Dow Chemical Co., Ltd. Fluoropolymer electrolytes such as resins, ethylene-tetrafluoroethylene copolymer resin membranes, resin membranes based on trifluorostyrene, and hydrocarbon resin membranes with sulfonic acid groups are generally commercially available. Examples thereof include a solid polymer electrolyte membrane, a membrane in which a polymer microporous membrane is impregnated with a liquid electrolyte, and a membrane in which a porous body is filled with a polymer electrolyte. The thickness of the electrolyte membrane 10 is usually about 15 to 150 μm.

  The catalyst layer 20 has a thickness of 10 to 30 μm as a whole, and includes at least catalyst particles 31, a conductive carrier 32, and an electrolyte resin (not shown in FIG. 1). The catalyst layer 20 has a three-layer structure, and includes a first layer 21 that is in contact with the electrolyte membrane 10, a second layer 22 that is an intermediate layer, and an outer layer that is in contact with a gas diffusion layer (not shown). Layer 23. The thickness of the first layer 21 is 1 to 3 μm, and the thickness of the second layer 22 is 3 to 9 μm.

  The first layer 21 is composed of a conductive carrier 32 carrying catalyst particles 31 and an electrolyte, and is a highly durable layer compared to the second layer 22 and the third layer 23. The means for achieving high durability is not limited. For example, as the first means, in the illustrated example, the first layer 21 is the catalyst particles 31 in the second layer 22 and the third layer 23. Those having an average particle diameter larger than that of the catalyst particles and having an average particle diameter of 4 nm or more are used.

  Specific examples of the catalyst particles 31 include Pt or an alloy catalyst of Pt and other metals. Specific examples of the alloy catalyst include an alloy of Pt and at least one metal selected from ruthenium, iridium, rhodium, palladium, osmium, tungsten, lead, iron, gold, and the like.

  The conductive carrier 32 has only to have a specific surface area for supporting the catalyst particles 31 in a desired dispersed state, and has sufficient electronic conductivity as a current collector. The main component is carbon. Preferably there is. Specific examples include carbon particles made of carbon black, activated carbon, coke, natural graphite, artificial graphite and the like.

  The electrolyte is not particularly limited, and examples thereof include the same solid polymer electrolyte as that used for the electrolyte membrane 10.

  In the first layer 21, as a second means for making the layer more durable compared to the second layer 22 and the third layer 23, as the catalyst particles 31, as active species, against potential fluctuations Pt which is difficult to elute or an alloy catalyst with Pt may be used. Specific alloys include PtIr and PtAu. Further, as a third means, it is also possible to use carbon particles having high crystallinity as the conductive carrier 32. The first to third means may be used individually, or the first layer 21 may be formed by appropriately combining two or more.

  The second layer 22 is composed of a conductive carrier 32 carrying catalyst particles 31 and an electrolyte, and is a layer having superior catalytic activity as compared with the first layer 21 and the third layer 23. The means for forming a layer having excellent catalytic activity is not limited. For example, as the first means, in the illustrated example, the second layer 22 is used as the catalyst particles 31 than the catalyst particles in the first layer 21. Also, those having a small average particle diameter and an average particle diameter of 4 nm or less are used. As a second means for forming a layer having excellent catalytic activity, an alloy catalyst having a lower catalytic activity than the catalyst particles in the first layer 21 but having a high catalytic activity, such as PtFe or PtMn, may be used. . The second layer 22 may be formed using a catalyst that satisfies both the first means and the second means.

  In the second layer 22, the conductive carrier 32 may be the same conductive carrier as that used in the first layer 21, and the electrolyte is a solid polymer similar to that used in the electrolyte membrane 10. It may be an electrolyte.

  The third layer 23 is a layer having a lower catalyst density or no catalyst compared to the first layer 21 and the second layer 22. The porosity is preferably higher than that of the first layer 21 and the second layer 22. Due to the presence of the third layer 23, the total pore volume inside the catalyst layer 20 increases, and it becomes difficult for gas supply failure to occur due to pore closure inside the catalyst layer 20 by generated water generated during power generation, and at the same time, the catalyst layer 20 The amount of product water taken out by water vapor increases due to an increase in the internal surface area. Therefore, as a whole catalyst layer, while satisfying both high durability and high performance, it is possible to generate power stably under higher humidification conditions. On the other hand, in the low humidification environment, the third layer 23 stops functioning and suppresses excessive drainage in order to dry from the outside of the catalyst layer, that is, the third layer 23.

  Preferably, the catalyst density of the third layer 23 is 40% or less (including 0%) in terms of the weight ratio of the conductive support, thereby comparing with the first layer 21 and the second layer 22. Thus, the layer has a low catalyst density or no catalyst. As described above, since the power generation performance is ensured by the first layer 21 and the second layer 22, the third layer 23 may not expect the power generation performance itself. By lowering the catalyst density, the production cost of the catalyst layer can be reduced.

  Preferably, in the third layer 23, the conductive carrier has water repellency. An example of a conductive carrier having high water repellency is acetylene black. High water repellency may be imparted by adding a water repellent such as PTFE to a normal conductive carrier. Thereby, the control of the generated water is further ensured. Preferably, the third layer 23 has a smaller amount of electrolyte mixed therewith than the first layer 21 and the second layer 22. Thereby, the spontaneous power generation function stop in the low humidity environment described above can be made more effective.

  In the third layer 23, the catalyst particles 31 may be the same as the catalyst particles used in the first layer 21 or the second layer 22 when used, and more preferably the second layer 22. The catalyst particles used in the above. In addition, the conductive carrier 32 may be the same conductive carrier as that used in the first layer 21 or the second layer 22, and the electrolyte has the same solid content as that used in the electrolyte membrane 10. It may be a molecular electrolyte.

  Although not shown in FIG. 1, in the membrane electrode assembly according to the present invention, the catalyst layer on the anode side may be the same as the catalyst layer 20 on the cathode side described above. Since the performance is not greatly affected, a conventional catalyst layer having a single-layer structure or a two-layer structure can also be used. Further, as described based on the conventional example of FIG. 4, a gas diffusion layer is laminated outside the cathode side catalyst layer and the anode side catalyst layer to form a membrane electrode assembly for a fuel cell according to the present invention. The Furthermore, one fuel cell called a single cell is formed by sandwiching the membrane electrode assembly with a separator having a gas flow path.

  Although it does not specifically limit as a gas diffusion layer used with the membrane electrode assembly of this invention, The layer which uses a carbon cloth or carbon paper as a base material is preferable. In order to improve water repellency, the substrate may contain a water repellent such as PTFE.

  Hereinafter, the present invention will be described more specifically with reference to examples. In addition, this invention is not limited only to the following Example.

[Example 1]
A perfluorocarbon sulfonic acid film having a thickness of about 30 μm was prepared as an electrolyte film. On the cathode side of the electrolyte membrane, an ink-like mixture obtained by mixing 70% by weight of Pt having a catalyst particle diameter of 6 nm and 70% by weight of ethanol and a solution of perfluorocarbon sulfonic acid in ethanol is screen-printed and dried. A first catalyst layer having a basis weight of 0.2 mg Pt / cm ² was formed. At this time, the thickness of the first catalyst layer was about 2.5 μm.

Next, an ink in which a catalyst-carrying carbon carrying 50% by weight of a PtCo alloy (atomic ratio 5: 1) having a catalyst particle diameter of 4 nm and an ethanol solution of perfluorocarbon sulfonic acid are mixed on the first catalyst layer. The resulting mixture was screen-printed and dried to form a second catalyst layer having a catalyst basis weight of 0.2 mg Pt / cm ² . At this time, the thickness of the second catalyst layer was about 5.5 μm.

Next, an ink-like mixture obtained by mixing 30% by weight of Pt with a catalyst particle diameter of 2 nm on the second catalyst layer and an ethanol solution of perfluorocarbon sulfonic acid is screen-printed and dried. Thus, a third catalyst layer having a catalyst basis weight of 0.1 mg Pt / cm ² was formed. As the supported carbon at this time, acetylene black having high water repellency was used. The total thickness of the catalyst layer was about 15 μm.

As the catalyst layer on the anode side, the catalyst weight is obtained by screen-printing and drying an ink-like mixture obtained by mixing 60% by weight of Pt having a catalyst particle diameter of 3 nm and ethanol solution of perfluorocarbon sulfonic acid. A catalyst layer of 0.2 mg Pt / cm ² was formed. The thickness of the anode side catalyst layer at this time was about 4.0 μm.

  The above electrolyte membrane with a catalyst layer was sandwiched between carbon paper having a thickness of about 200 μm treated with PTFE and subjected to heat press, and heat-pressed at 120 ° C. to obtain a membrane electrode assembly.

[Example 2]
A perfluorocarbon sulfonic acid film having a thickness of about 30 μm was prepared as an electrolyte film. An ink-like mixture in which 60% by weight of a PtIr alloy catalyst having a catalyst particle diameter of 6 nm (atomic ratio of 3: 1) and an ethanol solution of perfluorocarbon sulfonic acid are mixed on the cathode side of the electrolyte membrane. Was screen-printed and dried to form a first catalyst layer having a catalyst basis weight of 0.1 mg Pt / cm ² . At this time, the thickness of the first catalyst layer was about 2.5 μm.

Next, an ink in which a catalyst-carrying carbon carrying 50% by weight of a PtCo alloy (atomic ratio 5: 1) having a catalyst particle diameter of 4 nm and an ethanol solution of perfluorocarbon sulfonic acid are mixed on the first catalyst layer. The resulting mixture was screen-printed and dried to form a second catalyst layer having a catalyst basis weight of 0.3 mg Pt / cm ² . At this time, the thickness of the second catalyst layer was about 8.0 μm.

Next, an ink-like mixture obtained by mixing 30% by weight of Pt with a catalyst particle diameter of 2 nm on the second catalyst layer and an ethanol solution of perfluorocarbon sulfonic acid is screen-printed and dried. Thus, a third catalyst layer having a catalyst basis weight of 0.1 mg Pt / cm ² was formed. As the supported carbon at this time, acetylene black having high water repellency was used. The total thickness of the catalyst layer was about 17 μm.

As the catalyst layer on the anode side, the catalyst weight is obtained by screen-printing and drying an ink-like mixture obtained by mixing 60% by weight of Pt having a catalyst particle diameter of 3 nm and ethanol solution of perfluorocarbon sulfonic acid. A catalyst layer of 0.2 mg Pt / cm ² was formed. The thickness of the anode side catalyst layer at this time was about 4.0 μm.

  The above electrolyte membrane with a catalyst layer was sandwiched between carbon paper having a thickness of about 200 μm treated with PTFE and subjected to heat press, and heat-pressed at 120 ° C. to obtain a membrane electrode assembly.

[Comparative Example 1]
A membrane / electrode assembly was prepared in the same manner as in Example 1 except that the same cathode-side catalyst layer as in Example 1 was used as the cathode-side catalyst layer except that the third catalyst layer was not provided.

[Comparative Example 2]
A perfluorocarbon sulfonic acid film having a thickness of about 30 μm was prepared as an electrolyte film. On the cathode side of the electrolyte membrane, an ink-like mixture obtained by mixing 70% by weight of Pt having a catalyst particle diameter of 6 nm and 70% by weight of ethanol and a solution of perfluorocarbon sulfonic acid in ethanol is screen-printed and dried. A catalyst layer having a basis weight of 0.4 mg Pt / cm ² was formed. At this time, the thickness of the catalyst layer was about 5.0 μm.

The same catalyst layer as that of Example 1 was formed on the anode side.
The above electrolyte membrane with a catalyst layer was sandwiched between carbon paper having a thickness of about 200 μm treated with PTFE and subjected to heat press, and heat-pressed at 120 ° C. to obtain a membrane electrode assembly.

[Comparative Example 3]
A perfluorocarbon sulfonic acid film having a thickness of about 30 μm was prepared as an electrolyte film. An ink-like mixture in which 50% by weight of a PtCo alloy catalyst (atomic ratio 5: 1) having a catalyst particle diameter of 4 nm is mixed with an ethanol solution of perfluorocarbon sulfonic acid on the cathode side of the electrolyte membrane. Was screen-printed and dried to form a catalyst layer having a catalyst basis weight of 0.4 mg Pt / cm ² . At this time, the thickness of the catalyst layer was about 11 μm.

The same catalyst layer as that of Example 1 was formed on the anode side.
The above electrolyte membrane with a catalyst layer was sandwiched between carbon paper having a thickness of about 200 μm treated with PTFE and subjected to heat press, and heat-pressed at 120 ° C. to obtain a membrane electrode assembly.

[Evaluation test]
The membrane electrode assemblies of Examples 1 and 2 and Comparative Examples 1, 2, and 3 were sandwiched between separators to form fuel cells, and durability was evaluated from the relationship between the number of potential fluctuation cycles and the output voltage. The results are shown in FIG. Moreover, about Example 1 and 2 and the comparative example 1, humidification condition dependence was evaluated from the relationship between the humidification dew point and output voltage by the cathode side. The results are shown in FIG.

  From the results of FIG. 2, in Comparative Examples 1, 2, and 3, the comparative example 1 shows the best initial performance and durability, and Examples 1 and 2 have an initial performance substantially equivalent to that of Comparative Example 1. It turns out that it shows durability. The performance of Examples 1 and 2 is slightly better than that of Comparative Example 1 because the total amount of catalyst is slightly larger. From the results of FIG. 3, it can be seen that both Examples 1 and 2 can be stably operated in a wider range of conditions (the width of the cathode humidification dew point) than in Comparative Example 1.

  From this, it can be seen that the fuel cell having the membrane electrode assembly provided with the catalyst layer having the three-layer structure according to the present invention can satisfy both the durability and the power generation performance at the same time as compared with the conventional one.

The schematic diagram which shows a part of membrane electrode assembly by this invention. The graph which shows the relationship between the number of potential fluctuation cycles and output voltage in an Example and a comparative example. The graph which shows the relationship between the humidification dew point on the cathode side in an Example and a comparative example, and an output voltage. The schematic diagram for demonstrating a polymer electrolyte fuel cell.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Electrolyte membrane, 20 ... Cathode side catalyst layer, 21 ... 1st layer, 22 ... 2nd layer, 23 ... 3rd layer, 31 ... Catalyst particle, 32 ... Conductive carrier

Claims (7)

For a fuel cell, a cathode-side catalyst layer and an anode-side catalyst layer containing at least an electroconductive carrier supporting catalyst particles and an electrolyte are arranged opposite to both surfaces of the electrolyte membrane, and a gas diffusion layer is laminated on each catalyst layer. In the membrane electrode assembly of
The cathode-side catalyst layer has a three-layer structure and has an overall thickness of 10 to 30 μm. The first layer in contact with the electrolyte membrane has a thickness of 1 to 3 μm and is compared with the other two layers. The gas diffusion layer is a layer in which the catalyst performance is unlikely to deteriorate, and the second layer, which is an intermediate layer, has a thickness of 3 to 9 μm and is excellent in catalytic activity as compared with the other two layers. The membrane electrode assembly, wherein the third layer in contact with the layer is a layer having a lower catalyst density than the other two layers.   The first layer includes a catalyst or alloy catalyst in which the catalyst particles have an average particle diameter of 4 nm or more, the conductive carrier is carbon having high crystallinity, or the active species is difficult to elute against potential fluctuations. The membrane / electrode assembly according to claim 1, wherein the layer is a layer in which the catalyst performance is less likely to be lower than that of the other two layers by using one or a combination of two or more thereof. .   The second layer has a catalyst particle that has an average particle diameter of 4 nm or less and / or uses an alloy catalyst having a high catalytic activity, or both. The membrane electrode assembly according to claim 1, wherein the membrane electrode assembly is a layer having excellent activity. The third layer is a layer having a lower catalyst density than the other two layers by having a catalyst density of 40% or less by weight ratio of the conductive support. 2. The membrane electrode assembly according to 1.   The membrane electrode assembly according to any one of claims 1 to 4, wherein the third layer includes a water-repellent conductive carrier.   The membrane electrode according to any one of claims 1 to 5, wherein the third layer has a smaller amount of the mixed electrolyte than the first layer and the second layer. Joined body.   A fuel cell using the membrane electrode assembly according to any one of claims 1 to 6.

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