JP2006114471A - Separator for fuel cell, manufacturing method of the same, and solid oxide fuel cell - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a separator for a fuel cell excellent in carburization resistance, capable of restraining deterioration caused by carburization even in the case of using a hydrocarbon compound like methane gas as fuel gas, and to provide a manufacturing method of the same as well as a solid oxide fuel cell. <P>SOLUTION: The separator 8 for a fuel cell is formed by laminating a plurality of plate-shaped members 11, 12, 13 including a plate-shaped member 11 on which groove holes 14, 15 are formed, and an internal flow passage for guiding reaction gas is formed by covering openings of the groove holes 14, 15 by lamination of the plate-shaped members 11, 12, 13. An iron-based alloy, nickel-based alloy, or chromium-based alloy is used as a mother material of the plate-shaped members 11, 12, 13, and silver plating or copper plating is applied on both surfaces of the iron based alloy. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a separator for a fuel cell, a method for producing the same, and a solid oxide fuel cell (SOFC).

  As is well known, solid oxide fuel cells are being researched and developed as third-generation power generation fuel cells. Currently, three types of solid oxide fuel cells are proposed: cylindrical, monolithic, and flat-plate stacked. Of these structures, low-temperature solid oxide fuel cells are used. The flat plate type structure is widely adopted.

  In this flat plate type solid oxide fuel cell, a fuel cell stack is configured by alternately stacking power generation cells and separators with a current collector sandwiched therebetween.

The power generation cell has a laminated structure in which a solid electrolyte layer made of an oxide ion conductor is sandwiched between an air electrode (cathode) layer and a fuel electrode (anode) layer. Oxygen (air) as an oxidant gas is supplied to the air electrode side of the power generation cell, while fuel gas (H ₂ , CH _4, etc.) is supplied to the fuel electrode side. . The air electrode and the fuel electrode are both porous so that oxygen and fuel gas can reach the interface with the solid electrolyte.

  On the other hand, the separator has a function of electrically connecting the power generation cells and supplying a reaction gas to the power generation cells. From the surface facing the fuel electrode layer by introducing the fuel gas from the outer periphery thereof. A fuel passage to be discharged and an oxidant passage to introduce air as an oxidant gas from the outer peripheral portion and discharge the air from a surface facing the air electrode layer are provided. An air electrode current collector made of a sponge-like porous sintered metal plate such as an Ag-based alloy is disposed between the separator and the air electrode of the power generation cell, and between the separator and the fuel electrode of the power generation cell. Is disposed with a fuel electrode current collector made of a sponge-like porous sintered metal plate such as a Ni-based alloy.

In the solid oxide fuel cell having the above-described configuration, oxygen supplied to the air electrode side of the power generation cell via the separator and the air electrode current collector passes through the pores in the air electrode layer and interfaces with the solid electrolyte. In this area, electrons are received from the air electrode and ionized to oxide ions (O ²⁻ ). The oxide ions diffusely move in the solid electrolyte toward the fuel electrode. The oxide ions that have reached the vicinity of the interface with the fuel electrode react with the fuel gas at this portion to generate a reaction product (H ₂ O or the like), and discharge electrons to the fuel electrode. When these electrons are taken out by the anode current collector, a current flows and a predetermined electromotive force is obtained.

  By the way, in the flat plate type solid oxide fuel cell, when the operating temperature is set to a low temperature of 800 ° C. or lower, a stainless steel separator is often adopted as the separator.

  However, in the fuel cell employing the stainless steel separator, when a hydrocarbon compound such as methane gas is used as the fuel gas, carbon and carbon oxides are generated by the reforming reaction, and the fuel of the separator is generated by these products. There was a problem that the part exposed to the fuel gas such as the wall of the passage carburized and the separator deteriorated early.

  The present invention has been made in view of such circumstances, and has excellent carburization resistance, and even when a hydrocarbon compound such as methane gas is used as a fuel gas, and a fuel cell separator capable of suppressing deterioration due to carburization, and its It is an object of the present invention to provide a production method and a solid oxide fuel cell.

  The invention according to claim 1 is formed by laminating a plurality of plate-like members including a plate-like member provided with a slot, and the opening of the slot is covered by the lamination of the plate-like members. A separator for a fuel cell in which an internal flow path for inducing gas for use is formed, wherein an iron-based alloy, a nickel-based alloy, or a chromium-based alloy is used as a base material of the plate-like member, and the iron-based alloy It is characterized by being plated with silver, a silver alloy, copper or a copper alloy on both sides.

  The invention according to claim 2 is formed by laminating a plurality of plate-like members including a plate-like member provided with a slot, and the opening of the slot is covered by the lamination of the plate-like members. A separator for a fuel cell in which an internal flow path for inducing gas for use is formed, wherein an iron-based alloy, a nickel-based alloy, or a chromium-based alloy is used as a base material of the plate-shaped member, One of the surfaces where a plurality of iron-based alloys, nickel-based alloys, or chromium-based alloys are in contact with each other is plated with silver, a silver alloy, copper, or a copper alloy.

  Invention of Claim 3 is a manufacturing method of the parator of Claim 1 or Claim 2, Comprising: Both surfaces of the iron base alloy, nickel base alloy, or chromium base alloy used as the base material of the said plate-shaped member Alternatively, silver, silver alloy, copper, or copper alloy is plated on one surface, and the plate member is formed by pressing this, and then the formed plate member is laminated, and plating on the laminated surface is performed. These plate-like members are joined and integrated with each other by softening or melting.

  According to a fourth aspect of the present invention, in the fuel cell separator according to the first or second aspect, the wall surface of the internal channel is plated with silver, a silver alloy, copper, or a copper alloy. Instead, the surface of the base material is subjected to an aluminum diffusion coating treatment that diffuses and penetrates aluminum.

  According to a fifth aspect of the present invention, there is provided a fuel cell stack in which power generation cells and separators are alternately stacked, and a solid oxide that generates a power generation reaction by supplying a reaction gas to each of the power generation cells. In a fuel cell, the separator according to any one of claims 1, 2, and 4 is used as the separator.

According to the present invention, since not only the surface of the separator but also all the portions exposed to the fuel gas, such as the wall surface of the internal flow path, are plated with silver, copper, or each alloy, the resistance of the separator is increased. The carburizability can be greatly improved, and even when methane gas or the like is used as the fuel gas, deterioration of the separator due to carburization can be suppressed.
In addition, since silver or copper or each alloy plating is applied to both surfaces or one surface of the plate-like member, the separator is heated to soften or melt the silver or copper plating on the laminated surface of the plate-like member. Thus, the plate-like members can be easily joined together, and the production efficiency of the separator can be improved.
In particular, the wall surface of the internal channel is subjected to an aluminum diffusion coating treatment instead of the silver or copper plating or each alloy plating treatment, so that the high temperature corrosion resistance of the separator is further improved.

  FIG. 1 shows an embodiment of a solid oxide fuel cell according to the present invention. In FIG. 1, reference numeral 1 denotes a fuel cell stack. As shown in FIG. 1, the fuel cell stack 1 includes a power generation cell 5 in which a fuel electrode layer 3 and an air electrode layer 4 are arranged on both surfaces of a solid electrolyte layer 2, and a fuel electrode current collector outside the fuel electrode layer 3. 6, an air electrode current collector 7 outside the air electrode layer 4, and a separator 8 outside each current collector 6, 7 (the uppermost layer and the lowermost layer are end plates 9) are laminated in order. With the structure. The fuel cell stack 1 employs a sealless structure in which a gas leak prevention seal is not provided on the outer periphery of the power generation cell 5.

Here, the solid electrolyte layer 2 is composed of stabilized zirconia (YSZ) or the like to which yttria is added, and the fuel electrode layer 3 is composed of a metal such as Ni or Co or a cermet such as Ni—YSZ or Co—YSZ, and air. The electrode layer 4 is made of LaMnO ₃ , LaCoO ₃ or the like, the fuel electrode current collector 6 is made of a sponge-like porous sintered metal plate such as a Ni-based alloy, and the air electrode current collector 7 is made of an Ag-based alloy or the like. The sponge-like porous sintered metal plate.

  The separator 8 has a function of electrically connecting the power generation cells 5 and supplying a reaction gas to the power generation cells 5, and introduces fuel gas from the fuel manifold 21 to form the fuel electrode layer 3. And an internal flow path 10b that discharges air as an oxidant gas from the oxidant manifold 22 and discharges the air from the face that faces the air electrode layer 4, respectively. .

  As shown in FIG. 2, the separator 8 of the present embodiment is configured by laminating first to third plate-like members 11, 12, 13 formed in a substantially disk shape, and these plate-like members 11, 12. , 13 is a stainless steel plate (iron-based alloy), and silver or copper plating (or silver alloy or copper alloy plating is also possible) on both surfaces of the stainless steel plate.

  The first plate-like member 11 has a spiral first slot 14 extending from one end in the radial direction to the center and a spiral second slot 15 extending from the other end in the radial direction to the center. It is formed so as not to intersect. These first and second slot holes 14 and 15 are open in the laminating direction of the plate-like members.

  The second plate-like member 12 is provided with a fuel gas discharge port 16 penetrating in the stacking direction at a position corresponding to the terminal portion 14a of the first groove hole 14, and the third plate-like member 13 has a second An oxidant gas discharge port 17 penetrating in the stacking direction is provided at a position corresponding to the terminal portion 15 a of the groove 15.

  In the state where these first to third plate-like members 11, 12, 13 are laminated, the openings of the first and second groove holes 14, 15 are covered with the second and third plate-like members 12, 13. Thus, the internal flow paths 10a and 10b for the fuel gas and the oxidant gas are formed, and the fuel gas discharge port 16 and the oxidant gas discharge port 17 are connected to the internal flow paths 10a and 10b. It is formed at the center of both end faces adjacent to the bodies 6 and 7 respectively.

  In order to manufacture the separator 8, first, nickel plating as a base is applied to both surfaces of the SUS roll, then silver or copper plating is applied on the nickel plating, and then silver or copper plating is applied. The SUS roll is supplied to a press device, and the substantially first disk-shaped first to third plate members 11, 12 having the groove holes 14, 15 or the fuel gas discharge ports 16, 17 are formed by punching in the press device. 13 is formed, and then the formed first to third plate-like members 11, 12, and 13 are laminated and subjected to heat treatment to soften or melt the plating on the laminated surface. The plate members 11, 12, and 13 are bonded together. Thereby, the said separator 8 formed by integrating the 1st-3rd plate-shaped members 11, 12, and 13 can be manufactured. In the above manufacturing method, the first to third plate-like members 11, 12, and 13 are formed by punching after silver or copper plating. For example, after the punching, silver or copper is formed. In this way, it is possible to form a thin film by plating on the side wall surface of the slot or the like. Moreover, in the said manufacturing method, although nickel plating was performed as a base | substrate on both surfaces of a SUS roll, when using copper as plating applied to the surface of the 1st-3rd plate-shaped members 11, 12, 13, or When a nickel base alloy is used as a base material, it is possible to omit nickel plating as a base. In the above manufacturing method, the processing of the slot holes 14 and 15 and the gas discharge ports 16 and 17 of the first to third plate-like members 11, 12, and 13 is performed by punching with a press device. Of course, the present invention is not limited to this, and molding by etching is also possible.

  In the case of the end plate 9, a plate-like member in which the first groove hole 14 or the second groove hole 15 is formed and one opening (upper surface opening or lower surface opening) of the groove hole formed in the plate-like member. ) And a plate member on which the fuel gas discharge port 16 or the oxidant gas discharge port 17 is formed, respectively, so that the internal flow of the fuel gas is similar to that of the separator 8. The channel 10a or the internal channel 10b of the oxidizing gas can be formed.

  In the solid oxide fuel cell having the above configuration, the fuel gas introduced from the fuel manifold 21 into the internal flow path 10a of the separator 8 is a gas discharge port 16 provided at the center of one end face of the separator 8. The air as the oxidant gas discharged from the oxidant manifold 22 into the internal flow path 10b of the separator 8 is discharged toward the fuel electrode current collector 6 from the central portion of the other end face of the separator 8. The gas is discharged toward the air electrode current collector 7 from the gas discharge port 17 provided in. As a result, the fuel gas and the oxidant gas are spread over the entire surface of the fuel electrode layer 3 and the air electrode layer 4 while diffusing in the outer peripheral direction of the power generation cell 5, and a power generation reaction is performed at each electrode. .

  As described above, according to the present embodiment, a stainless steel plate (iron-based alloy) is used as the base material of the plate-like members 11, 12, and 13, and silver or copper plating is performed on both surfaces of the stainless steel plate. Since not only the surface of the separator 8 but also all the portions exposed to the fuel gas such as the wall surfaces of the internal flow paths 10a and 10b are covered with a thin film of silver or copper, the carburization resistance of the separator 8 is improved. This can greatly improve the deterioration of the separator 8 due to carburizing even when methane gas or the like is used as the fuel gas. In addition, since silver or copper plating is applied to both surfaces of the plate-like members 11, 12, and 13, the separator 8 is heated to apply silver or copper plating on the laminated surface of the plate-like members 11, 12, and 13. By softening or melting, the plate-like members 11, 12, 13 can be easily joined together, and the production efficiency of the separator 8 can be improved.

  In the above embodiment, silver or copper plating is applied to both surfaces of all the plate-like members 11, 12, 13 to be laminated. For example, as shown in FIG. The plated layer 18 of silver or copper may be formed only on one of the surfaces where the plate-like members 11, 12, 13 are in contact with each other. Even when the plate-like member has such a single-sided plating structure, the plate-like members can be joined by heating the separator 8 and softening or melting the plating layer 18 as described above. According to this method, the plating area (namely, the amount of plating material used) of the plate-like members 11, 12, and 13 can be reduced, and the cost can be reduced.

Further, in the present embodiment, the wall surface of the internal flow path (that is, the first groove hole 14, the second groove hole 15, the fuel gas discharge port 16, the oxidant gas discharge port 17) that is exposed to the reaction gas in particular. Instead of the above-described silver or copper plating treatment, an aluminum diffusion coating treatment may be applied to the surface of the base iron-based alloy. This aluminum diffusion coating treatment is a metal surface treatment that diffuses and permeates aluminum on the surface of the base material to form an Fe—Al alloy layer. For example, the base material is made of Fe—Al alloy powder and NH ₄ Cl powder. It is carried out by embedding it in a steel sealed case together with the preparation and heat-treating it. This Fe—Al alloy layer can further improve the high-temperature oxidation resistance and carburization resistance of the separator 8.
The aluminum diffusion coating treatment may be performed for each member before the first to third plate-like members 11, 12, 13 are laminated in the manufacturing process of the separator 8, or these plates may be used. It may be performed after the internal members 11, 12, 13 are laminated and joined to form the internal flow path.

  In the present embodiment, the separator 8 is formed by laminating the first to third plate-like members 11, 12, and 13. However, the number of laminated plate-like members is not limited to three. 4 or more is also possible. Further, in the present embodiment, the first and second groove holes 14 and 15 are collectively formed on one plate member, but may be formed separately on different plate members. In the present embodiment, the gas outlets 16 and 17 are provided at the center of the separator 8. For example, a plurality of gas outlets 16 and 17 are provided along the internal flow paths 10 a and 10 b. The gas for reaction (fuel gas, oxidant gas) can be discharged from the gas discharge ports 16 and 17 toward the current collectors 6 and 7 in a shower shape.

It is a principal part block diagram which shows one Embodiment of the solid oxide fuel cell which concerns on this invention. It is a disassembled perspective view which shows the separator of FIG. It is explanatory drawing which shows an example of the plating process of a plate-shaped member.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Fuel cell stack 5 Power generation cell 8 Separator 10a, 10b Internal flow path 11, 12, 13 Plate-like member 14, 15 Groove hole

Claims (5)

An internal flow path for inducing reaction gas by laminating a plurality of plate-like members including a plate-like member provided with a slot and covering the opening of the slot with the lamination of the plate-like members A separator for a fuel cell in which is formed,
An iron-base alloy, nickel-base alloy, or chromium-base alloy is used as the base material of the plate-like member, and silver, silver alloy, copper, or copper alloy is plated on both surfaces of the iron-base alloy. A separator for a fuel cell. An internal flow path for inducing reaction gas by laminating a plurality of plate-like members including a plate-like member provided with a slot and covering the opening of the slot with the lamination of the plate-like members A separator for a fuel cell in which is formed,
An iron-base alloy, nickel-base alloy, or chromium-base alloy is used as the base material of the plate-like member, and at the time of lamination, silver, a silver alloy, or copper is formed on any one of the faces that the plurality of iron-base alloys are in contact with each other. Alternatively, a separator for a fuel cell, which is plated with a copper alloy. It is a manufacturing method of the separator of Claim 1 or Claim 2,
The plate-like member is formed by applying silver or silver alloy or copper or copper alloy plating to both or one side of an iron-base alloy, nickel-base alloy, or chromium-base alloy that is a base material of the plate-like member, and pressing the plate. Each member is molded, and then the molded plate-like members are laminated, and the plating on the laminated surface is softened or melted so that the plate-like members are joined together and integrated. A method for manufacturing a separator.   For the wall surface of the internal flow path, aluminum diffusion that diffuses and permeates aluminum into the surface of the base material of the iron base alloy, nickel base alloy, or chromium base alloy instead of silver, silver alloy, copper or copper alloy plating 3. The fuel cell separator according to claim 1, wherein the separator is subjected to a coating treatment. In a solid oxide fuel cell having a fuel cell stack in which power generation cells and separators are alternately stacked, and supplying a reaction gas to each of the power generation cells to generate a power generation reaction,
A solid oxide fuel cell using the separator according to claim 1, claim 2, or claim 4 as the separator.

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