JP6047471B2 - Anode for fuel cell and single cell for fuel cell - Google Patents

Description

  The present invention relates to a fuel cell anode and a fuel cell single cell, and more particularly to a fuel cell anode used in a fuel cell single cell using a solid electrolyte as an electrolyte, and a fuel cell single cell using the same.

Conventionally, a support membrane type fuel cell single cell having an anode, a solid electrolyte layer, and a cathode and using the anode as a support is known. As the material for the anode, generally used is a cermet of nickel and a solid electrolyte having high ion conductivity such as yttria stabilized zirconia (8YSZ) containing 8 mol% Y ₂ O ₃ . Patent Document 1 preceding this application discloses a technique in which a mixed powder obtained by mixing a powder of composite particles in which YSZ fine particles are attached to nickel or nickel oxide particles and a powder of YSZ particles is used as an anode material. .

Japanese Patent Laid-Open No. 11-40169

  However, the prior art has problems in the following points. The anode desirably has high fuel gas diffusibility. However, if the anode is made highly porous in order to improve the gas diffusibility of the fuel gas, the strength as a support is insufficient, and cracking is likely to occur due to a thermal cycle caused by repeated operation / stop of the battery. On the other hand, it is conceivable to increase the strength by making the crystal phase of the solid electrolyte used for the anode material tetragonal. However, a solid electrolyte having a tetragonal crystal phase has strength but low ionic conductivity. Therefore, in this case, the anode characteristics deteriorate due to a decrease in the ionic conductivity of the anode.

  The present invention has been made in view of the above background, and was obtained by providing a fuel cell anode capable of improving strength while maintaining ionic conductivity, and a fuel cell single cell having the anode. Is.

One aspect of the present invention is an anode for a fuel cell that is used in a fuel cell single cell having an anode, a solid electrolyte layer, and a cathode, and using the anode as a support,
Comprising an anode base layer having both the function as the anode and the function as the support;
The anode base layer is composed of a mixture including a catalyst and a core-shell structure having a core part and a shell part covering the outer periphery of the core part, and the core part is mainly composed of tetragonal crystal phase. The shell portion is composed of an outer solid electrolyte whose crystal phase is mainly composed of cubic crystals ,
The inner solid electrolyte and the outer solid electrolyte are both zirconia-based solid electrolytes,
The zirconia solid _{electrolyte, Y 2 O 3, Sc 2} O 3, Yb 2 O 3, and the ZrO ₂ der Rukoto of one or more oxides selected from CaO is dissolved In the fuel cell anode.

  Another aspect of the present invention is a fuel cell single cell comprising the anode for a fuel cell, a solid electrolyte layer, and a cathode, wherein the anode for a fuel cell is used as a support.

The fuel cell anode has the above-described configuration. In particular, the anode for a fuel cell includes an anode base layer that has both an anode function and a support function, and the anode base layer is composed of a mixture including a catalyst and the core-shell structure. And the core part which forms the inside of a core-shell structure is comprised from the inner side solid electrolyte whose crystal phase has a tetragonal crystal as a main body. Tetragonal solid electrolytes have higher strength than cubic solid electrolytes. Therefore, even when the anode base layer is made highly porous, it can exhibit high strength as a support. Also, the shell portion forming the surface of the core-shell structure, the crystal phase is composed of an outer side solid electrolyte mainly composed of cubic. The cubic solid electrolyte has higher ionic conductivity than the tetragonal solid electrolyte. Therefore, the anode base layer can maintain ionic conductivity. Therefore, the fuel cell anode can improve strength while maintaining ionic conductivity.

  The fuel cell single cell uses the fuel cell anode as a support. Therefore, the fuel cell single cell has good anode characteristics and anode strength.

1 is a diagram schematically showing a cross-sectional structure of a fuel cell anode and a fuel cell single cell in Example 1. FIG. FIG. 3 is an explanatory view schematically showing the microstructure of an anode base layer in a fuel cell anode and a fuel cell single cell of Example 1. FIG. 3 is an explanatory view schematically showing a microstructure of an active layer in a fuel cell anode and a fuel cell single cell of Example 1. 6 is an explanatory view schematically showing the microstructure of an active layer in a fuel cell anode and a single fuel cell of Example 2. FIG.

  The anode for a fuel cell is applied to an anode in a solid electrolyte type fuel cell unit cell using a solid electrolyte as an electrolyte. As the solid electrolyte constituting the solid electrolyte layer, a solid oxide ceramic exhibiting oxygen ion conductivity can be used.

  A fuel cell using solid oxide ceramics as a solid electrolyte is called a solid oxide fuel cell (SOFC). The battery structure of the single fuel cell can be a flat plate having a layered anode as a support from the viewpoints of excellent electrical conductivity and high power generation performance.

  Specifically, the fuel cell unit cell is laminated with a solid electrolyte layer, an anode laminated on one surface of the solid electrolyte layer, and an intermediate layer on the other surface of the solid electrolyte layer with or without an intermediate layer. And a cathode as a support. The intermediate layer is mainly a layer for preventing a reaction between the material constituting the cathode and the material constituting the solid electrolyte layer. The cathode and the intermediate layer can be composed of one layer or two or more layers.

  The anode for fuel cells may be composed of one layer, or may be composed of two or more layers. However, the anode for a fuel cell needs to include an anode base layer having both an electrode function as an anode and a support function as a support. Specifically, the anode for a fuel cell includes, for example, an active layer disposed on the solid electrolyte layer side and the anode base layer laminated on the surface of the active layer opposite to the solid electrolyte layer side. can do. The active layer is mainly a layer for enhancing the electrochemical reaction on the anode side. The anode base layer is a layer capable of diffusing the supplied fuel gas.

  In this case, the thickness is larger than that of the active layer in order to perform the supporting function, and the ionic conductivity and strength of the anode base layer occupying most of the anode can be improved, which is advantageous in improving the anode characteristics. At the same time, an anode for a fuel cell with high structural reliability can be obtained. The anode base layer can be composed of one layer or two or more layers. Further, the outer shape of the active layer and the anode base layer can be configured to have the same size. Alternatively, the anode base layer may be configured to cover the remaining surface of the active layer except the surface in contact with the solid electrolyte layer.

  In the fuel cell anode, the anode base layer includes the core-shell structure. The core part of the core-shell structure is composed of an inner solid electrolyte whose crystal phase is mainly composed of tetragonal crystals, and the shell part of the core-shell structure is composed of an outer solid electrolyte whose crystal phase is mainly composed of cubic crystals. In the core part, “the crystal phase is mainly composed of tetragonal crystals” means that the outer part of the core part has cubic crystals that are the main crystal phase of the shell part in addition to the tetragonal crystal that is the main crystal phase of the core part. Can be included. Similarly, in the shell part, “the crystal phase is mainly composed of a cubic crystal” means that the main crystal phase of the core part other than the cubic crystal which is the main crystal phase of the shell part is formed on the inner part of the shell part. It means that a certain tetragonal crystal can be included. That is, the core-shell structure does not need to have a completely separated crystal phase between the core portion and the shell portion. This is because it is difficult to completely separate the crystal phase at the interface of each part. More specifically, the core-shell structure can have a structure in which the crystal phase sequentially changes from the center toward the surface, the tetragonal single phase, the mixed phase of tetragonal and cubic, and the cubic single phase. . Note that the configuration of the crystal phase of the core-shell structure can be measured by XRD.

In the fuel cell anode, the inner solid electrolyte and the outer solid electrolyte are both zirconia-based solid electrolytes.

According to this configuration, the inner solid electrolyte constituting the core portion of the core-shell structure is a zirconia-based solid electrolyte whose crystal phase is mainly tetragonal. A zirconia-based solid electrolyte having a tetragonal crystal phase has high strength. Therefore, according to this configuration, the strength of the core-shell structure is improved, which is advantageous for increasing the anode strength. In the above case, the outer solid electrolyte constituting the shell portion of the core-shell structure is a zirconia-based solid electrolyte whose crystal phase is mainly composed of cubic crystals. A zirconia solid electrolyte having a cubic crystal phase has a high oxygen ion conductivity. Therefore, according to this configuration, the oxygen ion conductivity of the fuel cell anode is improved, and the anode activity can be increased.

In the fuel cell anode, the zirconia-based solid electrolyte is specifically Y ₂ O ₃ , Sc ₂ O ₃ , Yb ₂ O ₃ ZrO in which one or more oxides selected from CaO are dissolved ₂ It is.

According to this configuration, there is an advantage that it is easy to balance the oxygen ion conductivity and strength of the core-shell structure in the anode base layer. The crystal phase of the zirconia-based solid electrolyte can be adjusted by selecting an appropriate solid solution amount (mol%) according to the type of oxide to be dissolved in ZrO ₂ . Both the inner solid electrolyte and the outer solid electrolyte may have the same type of oxide dissolved therein, or different types of oxides may be dissolved therein. The former is preferable from the viewpoint of stabilization of the crystal phase and the like.

In the fuel cell anode, ZrO ₂ in which Y ₂ O ₃ is dissolved can be preferably used as the zirconia-based solid electrolyte.

In this case, the balance between oxygen ion conductivity and strength of the core-shell structure in the anode base layer is excellent. Note that the crystal phase can be stabilized (partially stabilized) in a tetragonal crystal by dissolving ₃ mol% to 7 mol% of Y ₂ O ₃ in ZrO ₂ . Moreover, the crystal phase can be stabilized to cubic by dissolving 8 mol% to 11 mol% of Y ₂ O ₃ in ZrO ₂ .

  In the fuel cell anode, the anode base layer contains a catalyst in addition to the core-shell structure. Specific examples of the catalyst include nickel (Ni), nickel oxide (NiO, etc.), cobalt (Co), noble metals (Au, Ag, platinum group elements Ru, Rh, Pd, Os, Ir, Pt, preferably Pt, Pd, Ru) and the like can be exemplified. These can be used alone or in combination of two or more. More specifically, nickel and / or nickel oxide can be suitably used as the catalyst. Nickel (nickel oxide becomes nickel in the reducing atmosphere of the anode) has a sufficiently large affinity with hydrogen, which is suitably used for fuel gas, and is less expensive than other metals. Is appropriate.

  As described above, when the fuel cell anode includes an active layer and an anode base layer, the active layer may be composed of a mixture including a catalyst and a single solid electrolyte, or You may be comprised from the mixture containing a core-shell structure. "Single solid electrolyte" means a solid electrolyte that does not have a core-shell structure composed of a core part and a shell part in comparison with a core-shell structure. In the former case, there is an advantage that the electrode activity of the active layer can be easily improved by selecting a single solid electrolyte having high ionic conductivity. In the latter case, there is an advantage that not only the anode base layer but also the active layer can be improved in strength while maintaining ionic conductivity.

  As the catalyst contained in the active layer, those exemplified as the catalyst that can be used for the anode base layer can be used. Moreover, what was illustrated as a solid electrolyte which can be used for an inner side solid electrolyte and an outer side solid electrolyte can be used as a single-piece solid electrolyte which can be contained in an active layer. The single solid electrolyte that can be included in the active layer is preferably a solid electrolyte having a cubic crystal phase, more preferably a cubic crystal phase, from the viewpoint of easily ensuring high ionic conductivity. A zirconia-based solid electrolyte can be obtained. Further, as the core-shell structure that can be included in the active layer, the core-shell structure can be used.

  In the fuel cell anode, each of the mixtures constituting the anode base layer and the active layer can contain other components other than the above components, if necessary, as long as they are within the range where the above-described effects are exhibited. For example, the mixture constituting the anode base layer may contain a solid electrolyte that does not have a core-shell structure, alumina, and the like. Moreover, the mixture which comprises an anode base layer can contain a catalyst and a core-shell structure in the range of 30 / 70-70 / 30, for example, preferably 40 / 60-60 / 40 by mass ratio. . Moreover, the mixture which comprises an active layer contains a catalyst, a solid electrolyte, or a core-shell structure in the range of 30 / 70-70 / 30, for example, preferably 40 / 60-60 / 40 by mass ratio. be able to.

  In the fuel cell anode, the pore diameter of the pores contained in the anode base layer may be larger than the pore diameter of the pores contained in the active layer.

  In this case, the anode base layer is unlikely to be a gas diffusion rate-determining field for the fuel gas supplied to the active layer, and the diffusion of the fuel gas to the active layer is difficult to be inhibited. As a result, the gas diffusion resistance of the fuel gas can be easily reduced and the power generation characteristics of the single fuel cell can be easily improved. Even if the anode base layer is formed to be porous, as described above, the anode base layer can exhibit high strength as a support, and therefore, cracking and the like can be suppressed.

  The size relationship between the pore diameter of the anode base layer and the pore diameter of the active layer can be determined by cross-sectional observation with a scanning electron microscope (SEM). In addition, when the size relationship between both pore diameters cannot be clearly determined only by the cross-sectional observation, the average pore diameter of the anode base layer and the average pore diameter of the active layer can be measured and compared. In addition, the said average pore diameter is an average value of the pore diameter computed from the pore diameter distribution measured with the palm porometer etc.

  In the fuel cell anode, the porosity of the anode base layer may be in the range of 40 to 70%.

  In this case, the balance between strength as a support and gas diffusion of fuel gas is excellent. The porosity of the anode base layer is preferably 45% or more, more preferably 50% or more, from the viewpoint of improving gas diffusibility. The porosity of the anode base layer is preferably 60% or less, more preferably 55% or less, from the viewpoint of securing strength as a support.

  In the fuel cell anode, the porosity of the active layer can be in the range of 20 to 50%.

  In this case, there are advantages such as having many reaction points and high power generation performance. The porosity of the active layer is preferably 25% or more, more preferably 30% or more, from the viewpoint of an increase in the three-phase interface of the catalyst, the solid electrolyte, and the gas (pores) serving as reaction points. The porosity of the active layer is preferably 45% or less, more preferably 40% or less, from the viewpoint of an increase in the three-phase interface. The porosity mentioned above is a numerical value calculated by {1− (bulk density / apparent density)} × 100 by calculating the apparent density and the bulk density by the Archimedes method.

  In the fuel cell anode, the thickness of the anode base layer is preferably 200 μm or more, more preferably 400 μm or more, from the viewpoint of maintaining strength as a support. The thickness of the anode base layer is preferably 800 μm or less, more preferably 700 μm or less, from the viewpoint of gas diffusibility and the like. Further, the thickness of the active layer is preferably 10 μm or more, more preferably 15 μm or more, from the viewpoint of reaction activity or the like. The thickness of the active layer is preferably 25 μm or less, more preferably 20 μm or less, from the viewpoint of gas diffusibility and the like.

  In the fuel cell anode, the particle diameter D of the core-shell structure included in the anode base layer may be larger than the particle diameter d of the solid electrolyte or core-shell structure included in the active layer (d <D). . In this case, there is an advantage that the relationship of the pore size of the active layer <the pore size of the anode base layer is easily satisfied. In addition, the particle diameter said above can use the value measured by the intercept method from a SEM image. In addition, as the particle size described above, the particle size (diameter) d50 when the volume-based cumulative frequency distribution measured by the laser diffraction / scattering method indicates 50% is used for each powder raw material used for the production of each layer. You can also.

  In the fuel cell single cell, examples of the material constituting each layer include the following, but are not particularly limited.

Examples of the solid electrolyte constituting the solid electrolyte layer include zirconium oxide-based oxides such as yttria-stabilized zirconia (YSZ) and scandia-stabilized zirconia (ScSZ); lanthanum gallate-based oxides; CeO ₂ , CeO ₂ with Gd, Examples include cerium oxide-based oxides such as ceria-based solid solutions doped with one or more elements selected from Sm, Y, La, Nd, Yb, Ca, Dr, and Ho. it can. The thickness of the solid electrolyte layer is preferably 3 to 20 μm, more preferably 3 to 10 μm, from the viewpoint of ohmic resistance and the like.

  Examples of the cathode material include conductive perovskite oxides such as lanthanum-manganese oxides, lanthanum-cobalt oxides, and lanthanum-iron oxides, the perovskite oxides, the solid electrolytes, and the like. And the like. The thickness of the cathode is preferably 20 to 100 μm, more preferably 30 to 60 μm, from the viewpoint of reaction activity, gas diffusibility, and the like.

  Examples of the material for the intermediate layer include the cerium oxide-based oxide. The thickness of the intermediate layer is preferably 1 to 10 μm, more preferably 1 to 5 μm, from the viewpoints of ohmic resistance and prevention of element diffusion from the cathode.

  The fuel cell anode and the fuel cell single cell having the fuel cell anode can be preferably manufactured through the following first to third steps.

  The first step includes an unfired anode forming material that becomes a fuel cell anode by firing, an unfired solid electrolyte layer forming material that becomes a solid electrolyte layer by firing, and an intermediate layer by firing, if necessary. In this step, the unfired intermediate layer forming material is laminated in this order to obtain a laminate. The laminated body can be subjected to pressure bonding, degreasing and the like as necessary.

  When the anode for a fuel cell is composed of an anode base layer, the anode forming material can be specifically composed of an anode base layer forming material that becomes an anode base layer by firing. Further, when the anode for a fuel cell includes two layers of an anode base layer and an active layer, specifically, the anode forming material is an unfired anode base layer forming material that becomes an anode base layer by firing. And an unfired active layer forming material that becomes an active layer by firing.

  A sheet-like material can be used for the anode base layer forming material, the solid electrolyte layer forming material, and the intermediate layer forming material. As the active layer forming material, a sheet-like material or a paste-like material can be used.

  Specifically, an unfired material containing catalyst particles and raw material particles of the core-shell structure can be used as the anode base layer forming material. Further, as the active layer forming material, specifically, an unfired material containing catalyst particles and solid electrolyte particles or an unfired material containing catalyst particles and raw material particles of the core-shell structure is used. Can do.

As the raw material particles of the core-shell structure, for example, mother particles made of a zirconia-based solid electrolyte in which the above-described oxide is dissolved to form a tetragonal crystal, and dispersed and fixed on the surface of the mother particles And fine particles (child particles) made of a zirconia-based solid electrolyte in which the particle diameter is smaller than that of the mother particles and the above-described oxide is dissolved to form a cubic crystal phase. Raw material particles can be used. In addition, the anode base layer forming material and the active layer forming material can further include a pore-forming agent, a binder, a plasticizer, and the like, if necessary. Moreover, the pore diameter of the anode base layer and the pore diameter of the active layer can be adjusted by the particle diameter of the solid electrolyte particles in the anode base layer and the solid electrolyte particles in the active layer, the amount of pore forming agent added, and the like.

  A 2nd process is a process of baking the said laminated body simultaneously at 1250-1500 degreeC, for example. Thereby, the said core-shell structure can be made to exist in an anode base layer using the baking at the time of simultaneous baking. Thereby, a fired body in which an anode base layer, a solid electrolyte layer, and an intermediate layer as needed are laminated in this order, or a fired body in which an anode base layer, an active layer, a solid electrolyte layer, and an intermediate layer as needed are laminated in this order The body is obtained.

  In the third step, a cathode forming material that becomes a cathode by firing is layered on the surface of the intermediate layer in the fired body (or the surface of the solid electrolyte layer when there is no intermediate layer), for example, 900 to 1200 This is a step of baking at 0 ° C.

  A paste-like material can be used as the cathode forming material. The cathode-forming material can be applied in a layered manner to the surface of the intermediate layer (or the surface of the solid electrolyte layer when there is no intermediate layer) by a printing method or the like.

  Thereby, the fuel cell single cell which has the said anode for fuel cells and the said anode for fuel cells can be obtained.

  The manufacturing method can relatively easily form a fuel cell anode having an anode base layer including the core-shell structure and a fuel cell single cell having the fuel cell anode. Further, the above production method has the advantage that the fine particles are combined on the surface of the mother particles, so that the reactivity in the firing process is high and the core-shell structure having the above-described configuration can be easily formed in the anode base layer.

  In the above manufacturing method, in addition, a predetermined solid electrolyte is formed on the surface of the mother particle by coating or vapor deposition to prepare raw material particles, and the core-shell structure is made to exist in the anode base layer through the same procedure. It is also possible.

  In addition, each structure mentioned above can be arbitrarily combined as needed, in order to acquire each effect etc. which were mentioned above.

  Hereinafter, an anode for a fuel cell and a single cell for a fuel cell according to examples will be described with reference to the drawings. In addition, about the same member, it demonstrates using the same code | symbol.

Example 1
A fuel cell anode and a fuel cell single cell of Example 1 will be described with reference to FIGS. As shown in FIG. 1 to FIG. 3, the fuel cell anode 10 of this example includes an anode 1, a solid electrolyte layer 2, and a cathode 3, and a fuel cell single cell using the anode 1 as a support. 5 is used.

  The anode 10 for a fuel cell includes an anode base layer 12 that has both a function as the anode 1 and a function as a support. As shown in FIG. 2, the anode base layer 12 is composed of a mixture including a catalyst 121 and a core-shell structure 122 having a core portion 122a and a shell portion 122b covering the outer periphery of the core portion 122a. In the core-shell structure 122, the core part 122a is composed of an inner solid electrolyte whose crystal phase is mainly composed of tetragonal crystals, and the shell part 122b is composed of an outer solid electrolyte whose crystal phase is mainly composed of cubic crystals. Yes. In this example, specifically, the anode 10 for a fuel cell includes an active layer 11 disposed on the solid electrolyte layer 2 side, and an anode base layer laminated on the surface of the active layer 11 opposite to the solid electrolyte layer 2 side. 12.

  Further, as shown in FIG. 1, the fuel cell single cell 5 of this example has the fuel cell anode 10, the solid electrolyte layer 2, and the cathode 3, and the fuel cell anode of this example. 10 is a support. Specifically, the fuel cell single cell 5 includes a solid electrolyte layer 2 and a fuel cell anode 10 laminated on one surface of the solid electrolyte layer 2 (however, in this example, the active layer 11 is replaced with the solid electrolyte layer 2). And a cathode 3 laminated on the other surface of the solid electrolyte layer 2 with an intermediate layer 4 interposed therebetween, and is a flat unit cell having a fuel cell anode 10 as a support. These are described in detail below.

In this example, the solid electrolyte layer 2 is specifically formed from a zirconia solid electrolyte. More specifically, the zirconia-based solid electrolyte is yttria-stabilized zirconia (hereinafter, 8YSZ) containing 8 mol% of Y ₂ O ₃ , which is a zirconium oxide-based oxide, and has a thickness of 10 μm.

In this example, the active layer 11 in the fuel cell anode 10 is specifically composed of a mixture containing a catalyst 111 and a solid electrolyte 112. More specifically, the active layer 11 is formed of a cermet of Ni or NiO as the catalyst 111 and the solid electrolyte 112. In this example, the solid electrolyte 112 in the active layer 11 is a zirconia solid electrolyte whose crystal phase is cubic. More specifically, the anode base layer 12 in the fuel cell anode 10 is formed of a cermet of Ni or NiO as the catalyst 121 and a zirconia-based core-shell structure 122. In this example, the inner solid electrolyte of the core part 122a and the outer solid electrolyte of the shell part 122b in the core-shell structure 122 are both zirconia-based solid electrolytes. More specifically, the above-described zirconia-based solid electrolyte is ZrO ₂ in which Y ₂ O ₃ is solid-solved. However, the zirconia-based solid electrolyte in the solid electrolyte 112 in the active layer 11 and the outer solid electrolyte of the shell portion 122b is ZrO ₂ in which 8 mol% of Y ₂ O ₃ is dissolved, and in the inner solid electrolyte of the core portion 122a. The zirconia-based solid electrolyte is ZrO ₂ in which ₃ to 6 mol% of Y ₂ O ₃ is dissolved. Further, the particle diameter of the core-shell structure 122 included in the anode base layer 12 is larger than the particle diameter of the solid electrolyte 112 included in the active layer 11.

  In this example, the intermediate layer 4 is specifically formed of ceria (hereinafter, 10GDC) doped with 10 mol% of Gd, which is a cerium oxide-based oxide, and the thickness thereof is 5 μm.

In this example, specifically, the cathode 3 is formed in a layer form from a perovskite oxide. More specifically, the perovskite type _{oxide, La 1-x Sr x Co} 1-y F y O 3 (x = 0.4, y = 0.8, or less, LSCF) is. The thickness of the cathode is 50 μm.

  In this example, the pore diameter of the anode base layer 12 is formed to be relatively larger than the pore diameter of the active layer 11. Specifically, the porosity of the anode base layer 12 is 50%, and the porosity of the active layer 11 is specifically 35%.

  In this example, the fuel cell anode 10 (the anode base layer 12 and the active layer 11), the solid electrolyte layer 2, the intermediate layer 4, and the cathode 3 all have a rectangular shape in plan view. Further, the outer shapes of the fuel cell anode 10 (the anode base layer 12 and the active layer 11), the solid electrolyte layer 2, and the intermediate layer 4 are aligned to the same size. On the other hand, the outer shape of the cathode 3 is formed smaller than the outer shape of the solid electrolyte layer 2. That is, in this example, the fuel cell single cell 5 is configured such that the outer dimensions of the cathode 3 and the solid electrolyte layer 2 satisfy the relationship of the outer shape of the cathode 3 <the outer shape of the solid electrolyte layer 2.

  The effect of the fuel cell anode of this example will be described.

  The fuel cell anode 10 has the above-described configuration. In particular, the anode 10 for a fuel cell includes an anode base layer 12 that has both an anode function and a support function, and the anode base layer 12 is composed of a mixture including a catalyst 121 and a core-shell structure 122. . And the core part 122a which forms the inside of the core-shell structure 122 is comprised from the inner side solid electrolyte whose crystal phase is mainly a tetragonal crystal. Tetragonal solid electrolytes have higher strength than cubic solid electrolytes. Therefore, the anode base layer 12 can exhibit high strength as a support even when the porosity is increased. The shell portion 122b that forms the surface of the core-shell structure 122 is composed of an inner solid electrolyte whose crystal phase is mainly composed of cubic crystals. The cubic solid electrolyte has higher ionic conductivity than the tetragonal solid electrolyte. Therefore, the anode base layer 12 can maintain ionic conductivity. Therefore, the anode 10 for a fuel cell can improve the strength while maintaining the ionic conductivity.

  In the fuel cell anode 10 of this example, the inner solid electrolyte and the outer solid electrolyte are both composed of a zirconia-based solid electrolyte.

  Therefore, in the fuel cell anode 10 of the present example, the inner solid electrolyte constituting the core portion 122a of the core-shell structure 122 is a zirconia solid electrolyte whose crystal phase is mainly tetragonal. A zirconia-based solid electrolyte having a tetragonal crystal phase has high strength. Therefore, the anode 10 for fuel cells of this example is advantageous in improving the strength of the core-shell structure 122 and increasing the strength of the anode. The outer solid electrolyte constituting the shell portion 122b of the core-shell structure 122 is a zirconia-based solid electrolyte whose crystal phase is mainly composed of cubic crystals. A zirconia solid electrolyte having a cubic crystal phase has a high oxygen ion conductivity. Therefore, the anode 10 for fuel cells of this example can improve oxygen ion conductivity and increase anode activity.

  The anode 10 for a fuel cell of this example includes an active layer 11 disposed on the solid electrolyte layer 2 side, and an anode base layer 12 laminated on the surface of the active layer 11 opposite to the solid electrolyte layer 2 side. ing. Therefore, the fuel cell anode 10 of this example is thicker than the active layer 11 in order to exhibit the support function, and can improve the ionic conductivity and strength of the anode base layer 12 occupying most of the anode 1. Therefore, it is advantageous for improving anode characteristics and has high structural reliability.

  In the fuel cell anode 10 of this example, the solid electrolyte in the active layer 11 is composed of a zirconia solid electrolyte having a cubic crystal phase. Therefore, the anode 10 for a fuel cell of this example can ensure high oxygen ion conductivity even in the active layer 11 and is advantageous in enhancing anode activity.

  Further, the fuel cell anode 10 of the present example is configured such that the pore diameter of the pores included in the anode base layer 12 is larger than the pore diameter of the pores included in the active layer 11.

  Therefore, in the fuel cell anode 10 of this example, the anode base layer 12 is unlikely to be a gas diffusion rate-determining field of the fuel gas supplied to the active layer 11, and the diffusion of the fuel gas to the active layer 11 is difficult to be inhibited. As a result, the gas diffusion resistance of the fuel gas can be easily reduced, and the power generation characteristics of the single fuel cell 5 can be easily improved. Even when the anode base layer 12 is formed to be porous, as described above, the anode base layer 12 can exhibit high strength as a support, and therefore, cracks and the like can be suppressed.

  Further, the fuel cell anode 10 of this example satisfies the relationship of the particle diameter of the solid electrolyte 112 included in the active layer 11 <the particle diameter of the core-shell structure 122 included in the anode base layer 12. There is an advantage that the pore diameter is easily made larger than the pore diameter of the active layer 11.

  The effect of the fuel cell single cell of this example is demonstrated.

  The single fuel cell 5 uses a fuel cell anode 10 as a support. Therefore, the fuel cell single cell 5 has good anode characteristics and anode strength.

(Example 2)
As shown in FIG. 4, the anode 10 for the fuel cell of Example 2 is the anode for fuel cell of Example 1 in that the active layer 11 is composed of a mixture including the catalyst 111 and the core-shell structure 122. 10 and different. However, the particle diameter of the core-shell structure 1122 included in the anode base layer 12 is configured to be larger than the particle diameter of the core-shell structure 122 included in the active layer 11. Other configurations are the same as those of the anode 10 for the fuel cell of the first embodiment.

  In the fuel cell anode 10 of this example, since the core-shell structure 122 is used for the active layer 11, not only the anode base layer 12 but also the active layer 11 can be improved in strength while maintaining ionic conductivity. Can be advantageous. Other functions and effects are the same as those of the anode 10 for the fuel cell of Example 1.

  Moreover, the fuel cell single cell 5 of Example 2 uses the fuel cell anode 10 of Example 2 in place of the fuel cell anode 10 of Example 1, so that the fuel cell single cell of Example 1 is used. 5 and different. Other configurations are the same as those of the single fuel cell 5 of the first embodiment.

  The fuel cell single cell 5 of this example uses the fuel cell anode 10 of Example 2 as a support. Therefore, the fuel cell single cell 5 of this example can easily obtain good anode characteristics and anode strength. Other functions and effects are the same as those of the single fuel cell 5 of the first embodiment.

Hereinafter, it demonstrates more concretely using an experiment example.
<Experimental example>
(Material preparation)
Using a dry particle compounding device (“Nobilta” manufactured by Hosokawa Micron Co., Ltd.), yttria (partial) stabilized zirconia containing ₃ mol% of Y ₂ O ₃ using the force of compression, shear, impact, etc. of the device ( Hereinafter, 3YSZ) powder (average particle size: 2 μm) and 8YSZ powder (average particle size: 0.2 μm) were combined in a dry manner. Thereby, a core-shell structure having mother particles made of 3YSZ having a tetragonal crystal phase and 8YSZ fine particles (child particles) dispersed and fixed on the surface of the mother particles and having a particle diameter smaller than that of the mother particles. A raw material powder (average particle size: 2.4 μm) made of an aggregate of raw material particles was prepared. The average particle diameter is the particle diameter (diameter) d50 when the volume-based cumulative frequency distribution measured by the laser diffraction / scattering method shows 50% (hereinafter the same).
Next, NiO powder (average particle size: 0.7 μm), the raw material powder, carbon (pore forming agent), polyvinyl butyral (organic material), isoamyl acetate, 2-butanol and ethanol (mixed solvent). A slurry was prepared by mixing in a ball mill. The mass ratio of the NiO powder and the raw material powder is 60:40. The slurry was applied in a layer form on a plastic substrate using a doctor blade method and dried to prepare a sheet-form anode base layer forming material.

  NiO powder (average particle size: 0.7 μm), 8YSZ powder (average particle size: 0.5 μm), polyvinyl butyral (organic material), isoamyl acetate, 2-butanol and ethanol (mixed solvent) in a ball mill A slurry was prepared by mixing. The mass ratio of NiO powder and 8YSZ powder is 60:40. The slurry was applied in a layer form on a plastic substrate using a doctor blade method and dried to prepare a sheet-form active layer forming material.

  A slurry was prepared by mixing 8YSZ powder (average particle diameter: 0.5 μm), polyvinyl butyral (organic material), isoamyl acetate, 2-butanol and ethanol (mixed solvent) with a ball mill. The slurry was applied in a layer form on a plastic substrate using a doctor blade method and dried to prepare a sheet-shaped solid electrolyte layer forming material.

  A slurry was prepared by mixing 10 GDC powder (average particle size: 0.3 μm), polyvinyl butyral (organic material), isoamyl acetate, 2-butanol and ethanol (mixed solvent) with a ball mill. The slurry was applied in a layer form on a plastic substrate using a doctor blade method and dried to prepare a sheet-shaped intermediate layer forming material.

LSCF (La _0.6 Sr _0.4 Co _0.2 Fe _0.8 O ₃ ) powder (average particle size: 0.6 μm), ethyl cellulose (organic material), and terpineol (solvent) are mixed in a ball mill. Thus, a paste-like cathode forming material was prepared.

(First step)
A sheet-like anode base layer forming material, a sheet-like active layer forming material, a sheet-like solid electrolyte layer forming material, and a sheet-like intermediate layer forming material were laminated in this order to obtain a laminate. The obtained laminate was pressed and degreased using a CIP molding method. The CIP molding conditions were a temperature of 80 ° C., a pressing force of 50 MPa, and a pressing time of 10 minutes.

(Second step)
Next, the laminate was fired at 1350 ° C. for 2 hours. As a result, a sintered body was obtained in which the anode base layer (500 μm), the active layer (20 μm), the solid electrolyte layer (10 μm), and the intermediate layer (5 μm) were laminated in this order.

(Third step)
Next, a cathode forming material was applied to the surface of the intermediate layer in the sintered body by screen printing, and baked at 1100 ° C. for 2 hours to form a layered cathode (thickness 50 μm). The cathode forming material is not printed up to the outer edge of the intermediate layer, and the outer shape of the cathode layer is smaller than the outer shape of the solid electrolyte layer. Thereby, as shown in FIG. 1, the anode base layer, the active layer, the solid electrolyte layer, the intermediate layer, and the cathode were laminated in this order, and a fuel cell single cell having the anode as a support was obtained. Further, a fuel cell anode in which two layers of an anode base layer and an active layer were laminated was obtained. Since the above raw material powder is used when the anode base layer is obtained by firing, a core portion composed of an inner solid electrolyte mainly composed of tetragonal crystals in the anode base layer by firing, and a core portion A core-shell structure having a shell portion made of an outer solid electrolyte whose crystal phase is mainly composed of cubic crystals. Moreover, the porosity of the anode base layer was 50%, and the porosity of the active layer was 35%.

  As mentioned above, although the Example of this invention was described in detail, this invention is not limited to the said Example, A various change is possible within the range which does not impair the meaning of this invention.

DESCRIPTION OF SYMBOLS 1 Anode 2 Solid electrolyte layer 3 Cathode 5 Fuel cell single cell 10 Anode for fuel cells 12 Anode base layer 121 Catalyst 122 Core shell structure 122a Core part 122b Shell part

Claims (6)

A fuel cell anode (5) used for a fuel cell single cell (5) having an anode (1), a solid electrolyte layer (2), and a cathode (3) and using the anode (1) as a support. 10)
An anode base layer (12) having both the function as the anode (1) and the function as the support;
The anode base layer (12) is composed of a mixture including a catalyst (121) and a core shell structure (122) having a core portion (122a) and a shell portion (122b) covering the outer periphery of the core portion (122a). The core part (122a) is composed of an inner solid electrolyte whose crystal phase is mainly composed of tetragonal crystals, and the shell part (122b) is an outer solid electrolyte whose crystal phase is mainly composed of cubic crystals. Consists of
The inner solid electrolyte and the outer solid electrolyte are both zirconia-based solid electrolytes,
The zirconia solid _{electrolyte, Y 2 O 3, Sc 2} O 3, Yb 2 O 3, and the ZrO ₂ der Rukoto of one or more oxides selected from CaO is dissolved A fuel cell anode (10). 2. The anode for a fuel cell according to claim 1 , wherein the zirconia-based solid electrolyte is ZrO ₂ in which Y ₂ O ₃ is dissolved. An active layer (11) disposed on the solid electrolyte layer (2) side, and the anode base layer (12) laminated on the surface of the active layer (11) opposite to the solid electrolyte layer (2) side. The anode (10) for a fuel cell according to claim 1 or 2 , wherein the anode (10) is provided. The active layer (11) is composed of a mixture including the catalyst (111) and a single solid electrolyte (112), or is composed of a mixture including the catalyst (111) and the core-shell structure (122). The anode (10) for a fuel cell according to claim 3 , wherein the anode (10) is a fuel cell. The anode (10) for a fuel cell according to claim 3 or 4 , wherein the pore diameter of the anode base layer (12) is larger than the pore diameter of the active layer (11). It has the anode (10) for fuel cells of any one of Claims 1-5 , a solid electrolyte layer (2), and a cathode (3), The said anode (10) for fuel cells is provided. A fuel cell single cell (5), characterized by being a support.

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