KR20140087273A - Method for oxide catalyst collector of sofc stack having metal support cell - Google Patents

Abstract

According to the present invention, by minimizing contact resistance between a bipolar plate of a non-channel metal separation plate and a cathode collector body, a method for collecting an air electrode of an SOFC stack, including a metal support cell having enhanced cell performance and electric conductivity, can be provided.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method for collecting air holes in an SOFC stack including a metal support body cell,

The present invention relates to a method of collecting a cathode of a SOFC stack including a metal support type cell.

The solid oxide fuel cell is composed of an air electrode and a fuel electrode located on both surfaces of a solid electrolyte having oxygen ion conductivity. When oxygen and hydrogen are supplied to the air electrode and the fuel electrode, respectively, oxygen ions are generated through a reduction reaction of oxygen in the air electrode, and the hydrogen ions and oxygen ions react with each other through the solid electrolyte and the fuel electrode. At this time, the electrons generated in the fuel electrode are transmitted to the air electrode and are consumed, and current flows to the external circuit. Using this, the fuel cell produces electrical energy.

The solid electrolyte, the cathode and the anode form a unit cell and the unit cell produces a very limited amount of electrical energy. Therefore, the fuel cell stacks a plurality of unit cells to form a stack.

The separation plate has an air flow path for supplying oxygen to the air electrode and a flow path for a fuel for supplying hydrogen to the fuel electrode to prevent mixing of oxygen in the air electrode and hydrogen in the fuel electrode.

The separator is divided into a bipolar plate and a cell frame. In the bipolar plate, a cathode gas channel and a manifold hole are formed on one side of the metal plate, and an anode gas channel and a manifold hole are formed on the opposite side. The anode and the cathode of the adjacent unit cell are electrically connected in series. Therefore, the separation plate has a collecting function for the unit cell. In the cell frame, an air electrode and an anode gas manifold hole are formed at the same position as the bipolar plate, and the unit cell is fixed at the center thereof.

The manifold hole on the anode side is not difficult to perform a role of a gas channel in place of a channel formed by etching and plate-forming simultaneously with the current collection by stacking a plurality of metal current collectors such as Ni mesh or Ni-foam.

That is, since hydrogen flows through the fuel electrode, the contact resistance between the fuel electrode metal current collector and the metal bipolar plate hardly occurs.

On the other hand, the cathode flow path may be formed by an etching process or a machining process such as plate forming.

In this case, the etching process requires a high manufacturing cost and a long process time due to the characteristics of the manufacturing process, and the plate forming process using the press requires an expensive mold corresponding to the separating plate. Further, A separate post heat treatment process is required.

That is, since the air electrode side is an oxidizing atmosphere, the contact area between the metal-free metal bipolar plate and the air electrode metal current collector is further increased, thereby increasing the contact resistance of the stack.

According to the present invention, there is provided a method for collecting a cathode of an SOFC stack including a metal support type cell having improved battery performance and electrical conductivity by minimizing contact resistance between metals between a bipolar plate of a channelless metal separator and an air electrode current collector I want to.

A method for collecting air holes in an SOFC stack including a metal support cell, which is an aspect of the present invention, includes the steps of preparing a fuel cell unit cell comprising a metal support, a fuel electrode, a solid electrolyte layer and an air electrode, A step of airtightly joining the unit cells, a step of coating a cathode current collector layer for improving current collecting performance on one surface of the cathode, a step of disposing a cathode collector for collecting current and providing a flow path of air on one surface of the cathode current collector layer , Disposing a gasket type air electrode manifold sealing material between the cell frame and the bipolar plate, disposing a gasket type air electrode manifold sealing material between the cell frame and the bipolar plate, arranging the bipolar plate so that it contacts the air electrode current collector, So that the bipolar plate is in contact with the gasket type sealing material, Wherein the gasket sealing material between the bipolar plate and the cell frame is shrunk to secure airtightness by keeping the airtightness of the airtight space between the bipolar plate and the cell frame, Lt; 0 > C, and evaluating the performance while flowing air.

According to the present invention, it is possible to reduce the manufacturing cost and time of the separator plate and to reduce the contact resistance between the fuel cell unit cell and the separator plate. Also, if the gas tightness is confirmed in advance, the fuel cell can be packed again before the temperature of the stack is increased, thereby providing a fuel cell with excellent yield.

FIG. 1 (a) is a schematic view showing a state before application of a surface pressure, and FIG. 1 (b) is a schematic view showing application of a surface pressure as in the method proposed by the present invention.

The inventors of the present invention have confirmed that, in order to provide an economical solid oxide fuel cell stack to which a channel-free metal separator is applied, a cathode collector must serve as a cathode gas channel as well as a current collector.

Conventionally, in the case of forming the cathode gas channel by etching or machining, since the bipolar plate and the gas channel are one body, the problem of the contact resistance being generated because the present invention is separated into the bipolar plate of the channel and the cathode current collector Respectively.

That is, in the conventional cathode current collecting method, since the metal bipolar plate and the cathode metal collector are spatially separated by the glass sealing material, the glass sealing material is heated to 800 to 850 ° C to fuse the glass sealing material, The surface of the metal bipolar plate and the cathode current collector is first oxidized, and when the sealing material is fused to the metallic foil plate and the thickness thereof is decreased, the metal bipolar plate and the cathode current collector are brought into contact with each other to form an electrical contact .

The contact between the metal bipolar plate and the cathode metal current collector is not a contact between a pure metal and a metal but a contact with a metal oxide interposed therebetween. In comparison, it acts as a certain resistance element.

Accordingly, in the present invention, a method for stacking a stack of a metal separator, a metal support, and a cell in close contact with each other is devised so that intermetallic contact is established between the metal bipolar plate and the cathode metal collector We have devised a way to stack the stack by raising the stack temperature.

In order to realize this concept in the present invention, first, the metal current collector is relatively higher than the sealing material at the time of applying the surface pressure to the stack, so that the bipolar plate and the metal current collector are in contact with the cell. And the sealing material and the bipolar plate should be in contact with each other.

Secondly, the sealing material applied here must be applied with gasket type sealing material. That is, it is not a method of fusing at high temperature like glass, but it is pressed by surface pressure at room temperature and deforming is performed, and the airtightness of the seal is maintained. As the gasket type sealing material, TH866 model among the Thermiculite products of Flexitallic in the UK can be applied, and a sufficient surface pressure of 15 MPa or more is required.

Third, in order to withstand such a large surface pressure as described above, it is necessary to apply a metal support type SOFC cell having a ferritic stainless steel support excellent in strength.

Fourthly, it is necessary to hermetically bond the metal support type cell and the cell frame (not only the mechanical fixation but also the bonding at a level where there is no leakage of gas through the joint portion). Since the conventional glass seal can not withstand a surface pressure of 15 MPa or more , The metal supporting body cell should be hermetically bonded to the cell frame by brazing in advance.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments falling within the scope of the inventive concept may readily be suggested, but are also considered to be within the scope of the present invention.

The same reference numerals are used to designate the same components in the same reference numerals in the drawings of the embodiments.

1, a method for collecting air holes in a SOFC stack including a metal support body cell according to an embodiment of the present invention includes a metal support 110, a fuel electrode 120, a solid electrolyte layer 130, and an air electrode 140 Preparing a fuel cell unit cell; sealing the unit cell with the cell frame (160) accommodating the unit cell; coating a cathode current collector layer (310) on one surface of the air electrode to improve current collecting performance , Disposing an air electrode collector (300) on one side of the air electrode current collecting layer for collecting current and providing an air flow path, arranging a gasket type air electrode manifold sealing material (200) between the cell frame and the bipolar plate Placing the bipolar plate in contact with the air electrode current collector, applying a surface pressure to the bipolar plate, compressing and reducing the thickness of the air electrode current collector, A step of contacting the gasket-type sealing material with the gasket-type sealing material, the gasket-type sealing material between the bipolar plate and the cell frame being contracted by surface pressure to secure airtightness, and nitrogen And heating to 800 ° C and then cooling to an operating temperature of 700 to 750 ° C to evaluate the performance while flowing air.

The present invention is a fuel cell unit cell comprising a metal support 110, a fuel electrode 120, a solid electrolyte layer 130 and an air electrode 140 as a minimum unit of a stack, Configure the SOFC stack.

The electrolyte layer 130 is densely formed to block permeation of fuel gas and air, and is formed of a material having no electron conductivity but high oxygen ion conductivity. On the other hand, the fuel electrode 120 and the air electrode 140 are made of a porous material so that air and fuel gas are respectively diffused and supplied, and are formed of a material having high electron conductivity.

Oxygen ions are generated in the air electrode 140. Oxygen ions that have migrated to the fuel electrode 120 through the electrolyte layer 130 react with hydrogen of the fuel electrode 120 to generate water vapor. At this time, electrons are generated in the fuel electrode 120 and electrons are consumed in the air electrode 140. Therefore, when both electrodes are connected, electricity flows to the external circuit.

The cell frame 160 supports the stacked cells by hermetically bonding to the edges of the stacked cells by the bonding layer 150. [ The cell frame 160 is preferably a metal, and the bonding layer 150 preferably includes metal-ceramic brazing.

The cathode current collector paste is screen-printed on the air electrode of the fuel cell unit cell in which the cell frame is hermetically bonded to form the cathode current collector layer 310. In addition, the air electrode collector layer 310 may be formed by pasting a perovskite-type powder having excellent conductivity and sinterability over the air electrode to the air electrode, and screen-printing the paste to the air electrode to improve the collecting performance in the planar direction.

Further, after being screen-printed on the air electrode 140 without sintering, the air electrode 140 is heat-treated during the heat treatment of the stack, thereby improving the planar direction current collecting performance and improving the bonding property between the air electrode current collector 300 and the air electrode 140, It plays a role.

The air electrode composition of the home conductive layer 310 _{(La 1 -x, Ca x,} x = 0.1 ~ 0.2) (Co1-y-zCuxCrz, x = 0.5, y = 0.1 ~ 0.4, z = 0.1 ~ 0.2) O 3 and LaCoO consists of one or more of _three. It consists solely and complex.

The air electrode collector 300 is disposed on the surface of the air electrode collector layer 310. The current collector 300 collects current from the air electrode 140 and transmits the current to the bipolar plate and serves as a channel for air. Therefore, it is preferable to use a metal material which is easy to form a structure so as to have a gas flow path function and a current collecting function at the same time, as a current collector. The corrugated metal plate formed in a wavy pattern as shown in FIG. 1 has a flow path formed in the current collector itself, so that it is not particularly necessary to process the channel portion of the bipolar plate, which is expensive and not mass-producible. More preferably, the metal foam may be used as a current collector.

The current collector 300 may be made of the same material as the bipolar plate and the cell frame. More preferably, ferritic stainless steel is used.

A gasket-type sealing material is disposed on the cell frame.

Also, a bipolar plate 400 is formed on the current collector 300 and the gasket type sealing material. As shown in Fig. 1, the bipolar plate is disposed on the air electrode collector 300 and the sealing material. It is required that the thickness of the cell frame, the gasket sealing material and the cathode current collector should be small so that the current collector is disposed higher than the gasket type sealing material and pressed first when the surface pressure is applied.

That is, in the conventional stack construction method, since the temperature is raised while air is circulated up to about 500 ° C. in order to remove the binder of the glass sealing material, an oxide layer is formed on the surface of the metal current collector and the bipolar plate, Which causes a problem in contact resistance.

In order to solve this problem, in the present invention, it is preferable to apply the surface pressure in a state in which the current collector 300 and the sealing material 200 are in contact with the bipolar plate 400 in advance. By performing the contact first before the heat treatment as described above, oxide formation is prevented at a portion where the current collector and the sealing material directly contact the bipolar plate, thereby reducing the contact resistance.

At this time, it is preferable to apply a pressure of 15 MPa or more. When the applied surface pressure is less than 15 MPa, the sealing material 200 can not maintain a sufficient airtightness.

After the surface pressure application to the bipolar plate 400 is completed, the airtightness test is carried out. After the airtightness test is performed, the temperature is raised while nitrogen is flowing to 800 ° C for 12 hours, and then the operation temperature is 700 to 750 ° C. . At this time, flowing nitrogen into the air electrode at an elevated temperature is for minimizing oxide formation when forming a metal-to-metal contact between the metal current collector and the bipolar plate.

The air electrode manifold sealing material 200 is preferably positioned between the cell frame 160 and the bipolar plate 400 to prevent leakage of air and fuel gas supplied to the fuel cell unit cell 100. The bipolar plate 400 is preferably a compressive stress gasket chamber.

In the present invention, the present invention can be easily applied by using a gasket type sealing material 200 not containing an organic substance.

The air electrode current collector 300 is higher than the gasket type sealing material 200 in a state where the surface pressure is not applied, so that the bipolar plate should be in contact with the bipolar plate before the gasket type sealing material so that the surface pressure can be applied. For this purpose, the current collector of the air electrode is laminated at a relatively higher position than the gasket by 0.4-0.6 mm, so that the bipolar plate should be in contact with the bipolar plate before the gasket is applied. Therefore, the absolute thickness required for the cathode collector is mainly determined by the thickness of the cell frame and the thickness of the gasket.

Considering that the air electrode collector is deformed in the thickness direction by the surface pressure so that the bipolar plate touches the gasket and then the gasket shrinks and the gasket itself needs to shrink to 50% in order to maintain the airtightness of the seal. Should have.

That is, the air electrode current collector 300 is required to undergo elastic deformation of about 50 to 60% in the thickness direction at room temperature. In order to secure the above-mentioned strain, a corrugated metal or a metal foam structure . As shown in FIG. 1, when the corrugated air electrode current collector 300 is used, it is more preferable to fabricate a ferritic stainless steel plate.

In addition, as shown in FIG. 1, a case of forming a current collector and a bipolar plate on one surface of the air electrode is described below, but the same or similar effect is also obtained when the present invention is applied to a fuel electrode.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit or scope of the following claims. People will understand easily.

110: metal support
120: anode
130: solid electrolyte layer
140: air electrode
150: bonding layer
160: cell frame
200: Seal material
300: cathode collector
310: air electrode collector layer
400: bipolar plate
410: manifold hole

Claims (6)

Preparing a fuel cell unit cell composed of a metal support, a fuel electrode, a solid electrolyte layer, and an air electrode;
Sealing the unit cell with the cell frame accommodating the unit cell;
Coating a cathode current collector layer on one surface of the cathode to improve current collecting performance;
Disposing an air electrode collector on one surface of the air electrode collector layer to collect current and provide a flow path of air;
Disposing a gasket type air electrode manifold sealing material between the cell frame and the bipolar plate;
Disposing a bipolar plate in contact with the air electrode current collector;
Applying a surface pressure to the bipolar plate such that the air electrode current collector is compressed and reduced in thickness so that the bipolar plate contacts the gasket type sealing material;
Sealing the gasket-type sealing material between the bipolar plate and the cell frame by surface pressure to secure airtightness; And
And a step of cooling the air electrode region to 800 占 폚 while flowing nitrogen to the air electrode region and cooling the air electrode region to an operating temperature of 700 to 750 占 폚 to evaluate the performance while flowing air, Air pole collection method.
The method according to claim 1,
Wherein the current collector is a wavy or foam metal structure. ≪ RTI ID = 0.0 > 11. < / RTI >
The method according to claim 1,
Wherein the electrolyte layer and the cell frame are bonded to each other by metal-ceramic brazing.
The method according to claim 1,
Wherein the surface pressure is 15 MPa or more.
The method according to claim 1,
Wherein the sealing material comprises a metal supporting body cell as a gasket type sealing material.
The method according to claim 1,
Wherein the air electrode current collector comprises a metal supporting body cell having an elastic deformation force of 50 to 60%.

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