KR101220746B1 - Solid oxide fuel cell interconnect and coating method thereof - Google Patents

Abstract

The present invention relates to a metal connection material for a solid oxide fuel cell and a coating method thereof, comprising: stainless steel; And a manganese oxide (MnO) layer coated on the surface of the stainless steel and a spinel-based or perovskite-based oxide layer thereon. In addition, according to the present invention, in the method for coating a metal connection material for a solid oxide fuel cell, manganese oxide (MnO) is coated on the surface of the metal connection material, characterized in that the spinel-based or perovskite-based oxide coated thereon Provided is a coating method of a metal connecting material for a solid oxide fuel cell.
The coating layer formed according to the coating method of the metal interconnect material for the solid oxide fuel cell of the present invention can prevent or significantly delay the formation of chromium oxide due to the oxidation of the base material, which can greatly increase the service life of the separator as well as chromium. By preventing the formation of oxides, the effect of preventing chromium poisoning can also be greatly improved.

Description

Metal oxide fuel cell interconnect and coating method for solid oxide fuel cell

The present invention relates to a metal connection material for a solid oxide fuel cell and a coating method thereof, and more particularly, to prevent or reduce the formation of chromium oxide on the surface of a metal connection material such as a separator in a solid oxide fuel cell, thereby improving the life of the metal connection material. The present invention relates to a metal connection material for a solid oxide fuel cell and a coating method thereof which can be greatly improved.

The connecting material, which is one of the components of the solid oxide fuel cell (SOFC), basically connects the anode of one cell with the cathode of a neighboring cell, and physically blocks the air gas supplied to the cathode and the fuel gas supplied to the anode. It should play a role. In view of commerciality, such as workability and economics, the metal connecting material has superior characteristics as compared with the ceramic connecting material.

However, metal connectors have some disadvantages in use. Firstly, since the metal interconnect forms an oxide on the surface in a solid oxide fuel cell operating environment, the contact resistance is increased to reduce the electrical conductivity. In other words, the electrical conductivity of the metal connecting material is dependent on the characteristics of the oxide formed on the surface. This is why most metal interconnects for solid oxide fuel cells are designed based on Cr ₂ O ₃ -formers.

Secondly, Cr ₂ O ₃ -former metal interconnects make volatile Cr (VI) in solid oxide fuel cell operation. These Cr (VI) interferes with the normal electrochemical reaction of the battery and acts as a factor to reduce the battery performance. These two contradictory problems make it difficult to develop metal interconnects.

Therefore, the development of metal interconnects for solid oxide fuel cells may be accompanied by the development of alloys and surface treatment technology for controlling surface characteristics.

Looking at the conventional technology related to the metal connection material for a solid oxide fuel cell, it can be largely divided into Cr-based alloys based on Cr, ferritic stainless steels based on Fe (Ferritic STS), and Ni-based superalloys based on Ni. have.

First developed by Plansee Company, Cr-5Fe-1Y ₂ O ₃ was originally developed to replace ceramic interconnects in flat solid oxide fuel cells operating at high temperatures of about 1000 ° C. There is. In addition, since the operating temperature of the solid oxide fuel cell is lowered, Fe-based or Ni-based alloys are currently used in place of Cr-based alloys, which are poor in workability and expensive at operating temperatures below 800 ° C.

The representative ferrite Fe-Cr alloys developed so far are ZMG232 developed by Hitachi Metals and Crofer22 developed by ThyssenKrupp. The ZMG232 is a ferritic Fe-22Cr alloy containing 22% Cr and added 0.04% La and 0.22% Zr. ZMG232 is known to show better oxidation and electrical conductivity than the existing STS 430 in the temperature range of 700-1000 ℃. Crofer 22 developed by TyssenKrupp is also a ferrite Fe-Cr alloy. Looking at the characteristics of the Crofer 22, it is known to include a small amount of La of 0.08% in order to minimize the evaporation of Cr and lower the coefficient of thermal expansion, it is known that the characteristics are better than ZMG232.

The research flow of metal interconnects for solid oxide fuel cells has been introduced to the surface coating technology to enhance the surface properties with the development of alloys. The coating material is perovskite such as lanthanum-strontium-manganese oxide (LSM) and lanthanum-strontium-cobalt-iron oxide (LSCF) to increase the oxidation resistance and electrical conductivity of existing products and to prevent Cr evaporation. Coating oxide of the structure. Coating methods are applied to a variety of techniques, such as solution spraying, physical vapor deposition (PVD), thermal spray coating, slurry coating.

Summarizing the technology related to the perovskite ceramic coating technology so far, the coating layer should first of all have excellent electronic conductivity and similar thermal expansion coefficient to neighboring components. In addition, the adhesion of the coating layer is excellent so that peeling should not occur. It is also closely related to the thermal stress resistance of the coating layer.

Second, it is advantageous to form oxides such as spinel structures of MnCr ₂ O ₄ , CoCr ₂ O ₃ , and CoFe ₂ O ₄ at the interface between the coating layer and the substrate after prolonged exposure at high temperature. Because these oxides are non-insulating, they do not significantly increase the contact resistance at the interface. Instead, when an oxide such as insulating SrCrO ₄ or La ₂ O ₃ is formed as a reactant, the electrical conductivity of the coating layer is greatly reduced. Third, the structure of the coating layer should be dense. This is because it is possible to prevent the movement of oxygen diffusing inward through the coating layer from the outside and to prevent the external diffusion of the chromium component from the substrate.

In particular, the separator used in the solid oxide fuel cell generally uses a ferritic stainless material. In order to secure the high temperature electrical conductivity of the stainless separator and to suppress the oxide layer on the surface, a solution of (Mn, Co) ₃ O ₄ based spinel oxide or perovskite oxide coating such as LSM Judicial and spray coating methods are used.

However, in the conventional methods described above, as the usage time of the fuel cell increases, the chromium component of the stainless separator is oxidized at the interface of the coating layer and the separator to form a chromium oxide layer, thereby increasing electrical resistance at high temperature. In addition, the chromium component diffuses to the surface of the coating layer, thereby causing the chromium coating of the anode layer of the fuel cell to shorten the life of the separator.

Therefore, the method of increasing the life of the separator by preventing the formation of a chromium oxide layer when coating a metal connecting material such as a separator used in a solid oxide fuel cell or by delaying the growth rate as much as possible even if the chromium oxide layer is formed. This is required.

Accordingly, an object of the present invention is to provide a metal connecting material for a solid oxide fuel cell and a coating method thereof, which can improve the life of a fuel cell by preventing or reducing the formation of chromium oxide on the surface of the metal connecting material such as a separator in a solid oxide fuel cell. It is.

The present invention in one embodiment, stainless steel; And a manganese oxide (MnO) layer coated on the stainless steel surface and a spinel-based or perovskite-based oxide layer thereon.

The manganese oxide layer preferably has a thickness of 0.5-2 μm.

The spinel-based or perovskite-based oxide layer preferably has a thickness of 1-100 μm.

The metal connecting member is preferably a separator for a solid oxide fuel cell.

In another embodiment, the present invention provides a method for coating a metal coupling material for a solid oxide fuel cell, characterized by coating manganese oxide (MnO) on the surface of the metal coupling material, and coating a spinel-based or perovskite-based oxide thereon. It provides a coating method of a metal connection material for a solid oxide fuel cell.

The manganese oxide coating is preferably made by vacuum deposition, sputtering, chemical vapor deposition, vapor deposition or aerosol deposition.

The manganese oxide layer formed by the manganese oxide coating preferably has a thickness of 0.5-2 μm.

The spinel- or perovskite-based oxide coating is preferably made by solution spraying, physical vapor deposition (PVD), thermal spray coating, or slurry coating.

The spinel-based or perovskite-based oxide layer formed by the spinel-based or perovskite-based oxide coating preferably has a thickness of 1-100 μm.

The metal connecting member is preferably a separator for a solid oxide fuel cell.

The coating layer formed according to the coating method of the metal interconnect material for the solid oxide fuel cell of the present invention can prevent or significantly delay the formation of chromium oxide due to the oxidation of the base material, which can greatly increase the service life of the separator as well as chromium. By preventing the formation of oxides, the effect of preventing chromium poisoning can also be greatly improved.

Hereinafter, the present invention will be described in detail.

When coating the surface of a solid oxide fuel cell metal connecting material such as a separator made of stainless steel with a high temperature conductive spinel-based or perovskite-based oxide, the corrosion resistance of the stainless steel base material can be greatly improved. It is not possible to prevent the formation of chromium oxide on the surface. If the spinel- or perovskite-based oxide protective film is dense and the oxygen in the gas phase does not directly reach the surface of the base metal of the metal connecting material, the equilibrium oxygen partial pressure of the spinel- or perovskite-based oxide is higher than that of chromium oxide. Chromium oxide may be formed on the surface of the metal connector. That is, since the oxygen affinity of chromium contained in the base metal of the metal connecting material is greater than that of the oxide of the protective film, oxygen contained in the oxide of the protective film is separated to react with chromium to form chromium oxide.

Accordingly, the present inventors primarily form a manganese oxide (MnO) coating layer densely as a protective coating of the metal interconnect material for a solid oxide fuel cell, and when the existing spinel- or perovskite-based oxide is coated thereon, the manganese oxide is mixed with oxygen. Since the affinity of is greater than chromium, gaseous oxygen does not reach the surface of the metal interconnection material to prevent the formation of chromium oxide, or the growth rate is greatly slowed even if chromium oxide is formed. It has been found that the present invention can be improved, thereby completing the present invention.

The present invention is characterized by first forming a manganese oxide coating layer as a protective film of the metal connection material for a solid oxide fuel cell, and then coating a spinel-based or perovskite-based oxide thereon.

In the coating method of the present invention, the reason why the manganese oxide is selected as the primary coating material for the protective film of the metal interconnect material for the solid oxide fuel cell is that the oxygen equilibrium partial pressure of manganese oxide is lower than that of the chromium oxide, so that the chromium contained in the metal interconnect is This is because the oxygen cannot be deprived, and thus chromium oxide can not be formed unless oxygen reaches the gas state through the manganese oxide layer. It can be expected that elements with lower equilibrium oxygen partial pressures than chromium (eg, zirconium, yttrium, calcium, etc.) can be used for this purpose, but since the oxides of these elements are not electrically conductive at high temperatures, It is not suitable because the electrical resistance of the metal connecting material is large.

In addition, in order to exhibit the effect of preventing or reducing the formation of chromium oxide as described above, the manganese oxide layer should be dense so that the gaseous oxygen cannot pass through the manganese oxide layer. Commonly known deposition methods can be used to coat the dense manganese oxide layer on the surface of the metal interconnect for fuel cells. Deposition methods usable in the present invention include physical vapor deposition, such as vacuum deposition and sputtering, chemical vapor deposition or vapor deposition, or aerosol deposition and the like. In addition, the thickness of the manganese oxide layer formed by the manganese oxide coating is not limited, but preferably has a thickness range of 0.5-2㎛. If the thickness of the manganese oxide layer is less than 0.5 μm, it is difficult to control the thickness, and if the manganese oxide layer is too thin in this way, a chromium oxide layer may be formed, which may reduce the life of the metal connecting material and exceed 2 μm. In this case, the electrical resistance increases more than necessary, which may lower the performance of the fuel cell.

As described above, after the manganese oxide is coated on the surface of the metal connecting material, a spinel-based or perovskite-based oxide generally used for the protective coating of the metal connecting material for fuel cell is coated thereon.

In the method of the present invention, the spinel-based or perovskite-based oxide coating can be formed by the same method as conventional, for example, solution spraying, physical vapor deposition (PVD), thermal spray coating Or by slurry coating. In this case, the spinel-based or perovskite-based oxide layer formed by the spinel-based or perovskite-based oxide coating is not limited in thickness, but preferably has a thickness range of 1-100 μm. If the oxide layer has a thickness of less than 1 μm, the corrosion resistance may be reduced. If the thickness of the oxide layer is more than 100 μm, the electrical resistance may be increased more than necessary to reduce the performance of the fuel cell.

In the method of the present invention, the metal connecting member is not particularly limited but includes a separator plate.

Claims (10)

Stainless steel; And a manganese oxide (MnO) layer coated on the surface of the stainless steel and a spinel-based or perovskite-based oxide layer thereon.
The metal oxide connecting material of claim 1, wherein the manganese oxide layer has a thickness of 0.5-2 μm.
According to claim 1, wherein the spinel-based or perovskite-based oxide layer is a metal oxide connecting material for a solid oxide fuel cell, characterized in that having a thickness of 1-100㎛.
The solid oxide fuel cell metal connecting material of claim 1, wherein the metal connecting material is a separator plate for a solid oxide fuel cell.
In the method for coating a metal connection material for a solid oxide fuel cell,
A method of coating a metal connection material for a solid oxide fuel cell, characterized by coating manganese oxide (MnO) on the surface of the metal connection material and coating a spinel-based or perovskite-based oxide thereon.
6. The method of claim 5, wherein the manganese oxide coating is performed by vacuum deposition, sputtering, chemical vapor deposition, vapor deposition, or aerosol deposition.
The method of claim 5, wherein the manganese oxide layer formed by the manganese oxide coating has a thickness of 0.5-2 μm.
The method of claim 5, wherein the spinel-based or perovskite-based oxide coating is a metal connection material for a solid oxide fuel cell, characterized in that by the solution spray method, PVD (Physical Vapor Deposition), thermal spray coating or slurry coating Coating method.
The method of claim 5, wherein the spinel- or perovskite-based oxide layer formed by the spinel- or perovskite-based oxide coating has a thickness of 1-100 μm. .
6. The method of claim 5, wherein the metal connecting member is a separator for a solid oxide fuel cell.