JP5485444B1 - Fuel cell - Google Patents

Abstract

A fuel cell is provided that includes a porous support substrate having a gas flow path formed therein, and suppresses the occurrence of cracks at the gas discharge side end of the support substrate.
The fuel cell is a flat plate-like porous material having a longitudinal direction (x-axis direction), and a plurality of gas flow paths 11 penetrating in the longitudinal direction are spaced apart in the width direction (y-axis direction). And a power generating element portion provided on the main surface of the support substrate, in which a fuel electrode, a solid electrolyte, and an air electrode are laminated in this order. One end side and the other end side in the longitudinal direction of each gas flow path 11 correspond to the gas inflow side and the gas discharge side, and the main surface of the support substrate at the end surface on the other end side in the longitudinal direction (x-axis negative direction side) of the support substrate Or the part (E1) between a side end surface and a gas flow path, and the part (E2) between adjacent gas flow paths do not have a flat part, and exhibit the convex surface shape which protrudes in the other end side of a longitudinal direction. ing.
[Selection] Figure 19

Description

  The present invention relates to a fuel cell.

  Conventionally, “a flat porous support substrate having a longitudinal direction, in which a plurality of gas flow paths each penetrating in the longitudinal direction are formed at intervals in the width direction. Solid oxide fuel cell, which is a fired body, provided with a “substrate” and “a power generation element portion provided on the main surface of the support substrate and in which at least a fuel electrode, a solid electrolyte, and an air electrode are stacked in this order” Is widely known (see, for example, Patent Documents 1 and 2).

  In the fuel cell which is such a fired body, heat treatment is performed to supply a reducing gas to the fuel cell at a high temperature (for example, about 800 ° C.) before operating the fuel cell in order to obtain conductivity of the fuel electrode and the like. (Hereinafter referred to as “reduction treatment”) is performed, and the fuel cell is transferred from the non-reduced form to the reduced form.

  In such a fuel cell, “the gas (fuel gas) flows in one direction (same direction) in the longitudinal direction in each gas flow path, and excess gas discharged from the gas discharge port of each gas flow path to the external space is In the vicinity of the gas discharge port, a configuration in which it reacts with air (oxygen) in the external space and is burned can be employed.

  When this configuration is employed, cracks may occur at the gas discharge side end of the support substrate. This is considered based on the following reasons. First, due to the support substrate being porous, the air in the external space enters the inside of the gas discharge side end of the support substrate, and the excess gas described above and the air inside It reacts and burns. As a result, excessive thermal stress due to heat generation due to combustion is locally generated in the inside, and cracks are generated. Secondly, when the air in the external space enters the inside of the gas discharge side end of the support substrate, the inside which is a reductant is reoxidized. As a result, an excessive stress accompanying a dimensional change (oxidation expansion or contraction) due to re-oxidation is locally generated in the inside, and a crack is generated. It is desired to suppress the occurrence of such cracks.

JP-A-8-106916 JP 2008-226789 A

  An object of the present invention is to provide a fuel cell including a porous support substrate having a gas flow path formed therein, which can suppress the occurrence of cracks at the gas discharge side end of the support substrate. There is to do.

  The fuel cell according to the present invention includes the same support substrate and power generation element unit as described above. One end side and the other end side in the longitudinal direction of each gas flow path correspond to a gas inflow side and a gas discharge side, respectively.

  The feature of this fuel cell is that "the portion between the main surface or side end surface of the support substrate and the gas flow path" in the end surface on the other end side in the longitudinal direction of the support substrate does not include a flat portion, And it is in the convex surface shape which protrudes in the other end side of the said longitudinal direction (refer E1 of FIGS. 19-21 mentioned later).

  In the fuel cell according to the present invention, the “portion between the adjacent gas flow paths” on the end surface on the other end side in the longitudinal direction of the support substrate does not include a flat portion, and It is preferable to have a convex shape protruding to the other end side (see E2 in FIG. 19 described later).

  According to the above feature, the same part (see E1 in FIGS. 19 to 21 to be described later and E2 in FIG. 19 to be described later) has a planar configuration, or the other end in the longitudinal direction. It has been found that the occurrence of cracks at the gas discharge side end portion of the support substrate 10 can be suppressed as compared with a configuration having a flat portion while projecting to the side.

  Although details are unknown, this is because, when the end surface on the gas discharge side of the support substrate does not include a flat portion, the gas is generated at the gas discharge side end portion of the support substrate as compared with the configuration in which the end surface includes a flat portion. This is thought to be due to the fact that the thermal stress distribution at the end of the gas discharge side during combustion changes, and it is difficult for thermal stress concentration to occur at the end of the gas discharge side.

1 is a perspective view showing a fuel cell according to the present invention. FIG. 2 is a cross-sectional view corresponding to line 2-2 of the fuel cell shown in FIG. It is the top view which showed the state of the fuel electrode and interconnector which were embed | buried under the recessed part of the support substrate shown in FIG. It is a figure for demonstrating the operation state of the fuel cell shown in FIG. It is a figure for demonstrating the flow of the electric current in the operating state of the fuel cell shown in FIG. It is a perspective view which shows the support substrate shown in FIG. FIG. 3 is a cross-sectional view corresponding to FIG. 2 in a first stage in the manufacturing process of the fuel cell shown in FIG. 1. FIG. 3 is a cross-sectional view corresponding to FIG. 2 in a second stage in the manufacturing process of the fuel cell shown in FIG. 1. FIG. 3 is a cross-sectional view corresponding to FIG. 2 in a third stage in the manufacturing process of the fuel cell shown in FIG. 1. FIG. 4 is a cross-sectional view corresponding to FIG. 2 in a fourth stage in the manufacturing process of the fuel cell shown in FIG. 1. FIG. 6 is a cross-sectional view corresponding to FIG. 2 in a fifth stage in the manufacturing process of the fuel cell shown in FIG. 1. FIG. 7 is a cross-sectional view corresponding to FIG. 2 in a sixth stage in the manufacturing process of the fuel cell shown in FIG. 1. FIG. 8 is a cross-sectional view corresponding to FIG. 2 in a seventh stage in the manufacturing process of the fuel cell shown in FIG. 1. FIG. 7 is a cross-sectional view corresponding to FIG. 2 in an eighth stage in the manufacturing process of the fuel cell shown in FIG. 1. It is a figure which shows the whole shape of the end surface by the side of the gas discharge | emission of a support substrate when the support substrate of the fuel cell shown in FIG. 1 is seen from a direction perpendicular to the longitudinal direction and the width direction. FIG. 16 is a view corresponding to FIG. 15 illustrating a first modification of the overall shape of the end surface on the gas discharge side of the support substrate. FIG. 16 is a view corresponding to FIG. 15 showing a second modification of the overall shape of the end surface on the gas discharge side of the support substrate. It is a figure which shows the whole shape of the end surface by the side of the gas discharge | emission of a support substrate when the support substrate of the fuel cell shown in FIG. 1 is seen from a longitudinal direction. It is 19-19 sectional drawing of FIG. It is 20-20 sectional drawing of FIG. It is a figure corresponding to FIG. 19 which shows the 3rd modification of the whole shape of the end surface by the side of the gas discharge | emission of a support substrate. It is sectional drawing corresponding to FIG. 2 of the 2nd modification of the fuel cell which concerns on this invention. It is sectional drawing corresponding to FIG. 3 of the 3rd modification of the fuel cell which concerns on this invention.

(Constitution)
FIG. 1 shows a structure of a solid oxide fuel cell (SOFC) according to an embodiment of the present invention. This SOFC structure is electrically connected in series to the upper and lower surfaces (main surfaces (planes) on both sides parallel to each other) of the flat support substrate 10 having a longitudinal direction (x-axis direction). (In this example, four) power generation element portions A having the same shape are arranged at a predetermined interval in the longitudinal direction and have a so-called “horizontal stripe type” configuration.

  The shape of the entire SOFC structure viewed from above is, for example, a rectangle having a length of 5 to 50 cm in the longitudinal direction and a length of 1 to 10 cm in the width direction (y-axis direction) perpendicular to the longitudinal direction. is there. The total thickness of the SOFC structure is 1 to 5 mm. The entire SOFC structure has a vertically symmetrical shape with respect to a plane passing through the center in the thickness direction and parallel to the main surface of the support substrate 10. Hereinafter, in addition to FIG. 1, the details of the SOFC structure will be described with reference to FIG. 2, which is a partial cross-sectional view of the SOFC structure corresponding to line 2-2 shown in FIG. 1. FIG. 2 is a partial cross-sectional view showing a configuration (part of) each of a typical pair of adjacent power generation element portions A and A and a configuration between the power generation element portions A and A. The configuration between the other power generation element portions A and A in other sets is the same as the configuration shown in FIG.

  The support substrate 10 is a flat plate-like fired body made of a porous material having no electronic conductivity. As shown in FIG. 6 to be described later, a plurality of fuel gas passages 11 (through holes are preferable in the present example) extending in the longitudinal direction are provided in the support substrate 10 in the width direction. They are formed at a predetermined interval. In this example, each recess 12 includes a bottom wall made of the material of the support substrate 10 and side walls closed in the circumferential direction made of the material of the support substrate 10 over the entire circumference (two side walls along the longitudinal direction and the width direction). A rectangular parallelepiped depression defined by two side walls).

The support substrate 10 can be made of, for example, CSZ (calcia stabilized zirconia). Alternatively, it may be composed of NiO (nickel oxide) and YSZ (8YSZ) (yttria stabilized zirconia), NiO (nickel oxide) and Y ₂ O ₃ (yttria), or MgO. (Magnesium oxide) and MgAl ₂ O ₄ (magnesia alumina spinel) may be used.

  The support substrate 10 may be configured to include “transition metal oxide or transition metal” and insulating ceramics. As the “transition metal oxide or transition metal”, NiO (nickel oxide) or Ni (nickel) is suitable. The transition metal can function as a catalyst for promoting a reforming reaction of the fuel gas (hydrocarbon-based gas reforming catalyst).

Further, as the insulating ceramic, MgO (magnesium oxide) or “mixture of MgAl ₂ O ₄ (magnesia alumina spinel) and MgO (magnesium oxide)” is preferable. Further, CSZ (calcia stabilized zirconia), YSZ (8YSZ) (yttria stabilized zirconia), Y ₂ O ₃ (yttria) may be used as the insulating ceramic.

  As described above, since the support substrate 10 contains “transition metal oxide or transition metal”, the gas containing the residual gas component before the reforming is supplied to the fuel through the numerous pores inside the porous support substrate 10. In the process of being supplied from the gas flow path 11 to the fuel electrode, the catalytic action can promote the reforming of the residual gas component before the reforming. In addition, the insulating property of the support substrate 10 can be ensured by the support substrate 10 containing insulating ceramics. As a result, insulation between adjacent fuel electrodes can be ensured.

  The thickness of the support substrate 10 is 1 to 5 mm. Hereinafter, only the configuration on the upper surface side of the support substrate 10 will be described in consideration of the fact that the shape of the structure is vertically symmetrical. The same applies to the configuration of the lower surface side of the support substrate 10.

  As shown in FIGS. 2 and 3, the entire fuel electrode current collector 21 is embedded (filled) in each recess 12 formed in the upper surface (upper main surface) of the support substrate 10. Therefore, each fuel electrode current collector 21 has a rectangular parallelepiped shape. A recess 21 a is formed on the upper surface (outer surface) of each fuel electrode current collector 21. Each recess 21a has a rectangular parallelepiped shape defined by a bottom wall made of the material of the fuel electrode current collector 21 and side walls closed in the circumferential direction (two side walls along the longitudinal direction and two side walls along the width direction). It is a depression. Of the side walls closed in the circumferential direction, two side walls along the longitudinal direction are made of the material of the support substrate 10, and two side walls along the width direction are made of the material of the fuel electrode current collector 21.

  The entire anode active portion 22 is embedded (filled) in each recess 21a. Accordingly, each fuel electrode active portion 22 has a rectangular parallelepiped shape. A fuel electrode 20 is configured by the fuel electrode current collector 21 and the fuel electrode active unit 22. The fuel electrode 20 (fuel electrode current collector 21 + fuel electrode active part 22) is a fired body made of a porous material having electron conductivity. The two side surfaces and the bottom surface along the width direction of each anode active portion 22 are in contact with the anode current collecting portion 21 in the recess 21a.

  A recess 21b is formed in a portion of the upper surface (outer surface) of each fuel electrode current collector 21 excluding the recess 21a. Each recess 21b has a rectangular parallelepiped shape defined by a bottom wall made of the material of the fuel electrode current collector 21 and side walls closed in the circumferential direction (two side walls along the longitudinal direction and two side walls along the width direction). It is a depression. Of the side walls closed in the circumferential direction, two side walls along the longitudinal direction are made of the material of the support substrate 10, and two side walls along the width direction are made of the material of the fuel electrode current collector 21.

  An interconnector 30 is embedded (filled) in each recess 21b. Accordingly, each interconnector 30 has a rectangular parallelepiped shape. The interconnector 30 is a fired body made of a dense material having electronic conductivity. The two side surfaces and the bottom surface along the width direction of each interconnector 30 are in contact with the fuel electrode current collector 21 in the recess 21b.

  The upper surface (outer surface) of the fuel electrode 20 (the fuel electrode current collector 21 and the fuel electrode active unit 22), the upper surface (outer surface) of the interconnector 30, and the main surface of the support substrate 10 form one plane (recessed portion). The same plane as the main surface of the support substrate 10 when 12 is not formed) is formed. That is, no step is formed between the upper surface of the fuel electrode 20, the upper surface of the interconnector 30, and the main surface of the support substrate 10.

The fuel electrode active part 22 may be composed of, for example, NiO (nickel oxide) and YSZ (8YSZ) (yttria stabilized zirconia). Or you may comprise from NiO (nickel oxide) and GDC (gadolinium dope ceria). The fuel electrode current collector 21 can be composed of, for example, NiO (nickel oxide) and YSZ (8YSZ) (yttria stabilized zirconia). Alternatively, it may be composed of NiO (nickel oxide) and Y ₂ O ₃ (yttria), or may be composed of NiO (nickel oxide) and CSZ (calcia stabilized zirconia). The thickness of the anode active portion 22 is 5 to 30 μm, and the thickness of the anode current collecting portion 21 (that is, the depth of the recess 12) is 50 to 500 μm.

  As described above, the fuel electrode current collector 21 includes a substance having electronic conductivity. The fuel electrode active part 22 includes a substance having electron conductivity and a substance having oxygen ion conductivity. The “volume ratio of the substance having oxygen ion conductivity with respect to the entire volume excluding the pore portion” in the anode active portion 22 is “having oxygen ion conductivity with respect to the entire volume excluding the pore portion” in the anode current collecting portion 21. It is larger than the “volume ratio of the substance”.

The interconnector 30 can be composed of, for example, LaCrO ₃ (lanthanum chromite). Alternatively, it may be composed of (Sr, La) TiO ₃ (strontium titanate). The thickness of the interconnector 30 is 10 to 100 μm.

  The entire surface excluding the central portion in the longitudinal direction of each portion where the plurality of interconnectors 30 are formed on the outer peripheral surface extending in the longitudinal direction of the support substrate 10 in a state where the fuel electrode 20 and the interconnector 30 are embedded in the respective recesses 12. Is covered with a solid electrolyte membrane 40. The solid electrolyte membrane 40 is a fired body made of a dense material having ionic conductivity and not electron conductivity. The solid electrolyte membrane 40 can be made of, for example, YSZ (8YSZ) (yttria stabilized zirconia). Or you may comprise from LSGM (lantern gallate). The thickness of the solid electrolyte membrane 40 is 3 to 50 μm.

  That is, the entire outer peripheral surface extending in the longitudinal direction of the support substrate 10 in a state where the fuel electrode 20 is embedded in each recess 12 is covered with a dense layer composed of the interconnector 30 and the solid electrolyte membrane 40. This dense layer exhibits a gas sealing function that prevents mixing of the fuel gas flowing in the space inside the dense layer and the air flowing in the space outside the dense layer.

  As shown in FIG. 2, in this example, the solid electrolyte membrane 40 includes the upper surface of the fuel electrode 20 (current collector 21 + active portion 22), both end portions in the longitudinal direction on the upper surface of the interconnector 30, and the support substrate. 10 main surfaces are covered. Here, as described above, no step is formed between the upper surface of the fuel electrode 20, the upper surface of the interconnector 30, and the main surface of the support substrate 10. Therefore, the solid electrolyte membrane 40 is flattened. As a result, compared with the case where a step is formed in the solid electrolyte membrane 40, the generation of cracks in the solid electrolyte membrane 40 due to stress concentration can be suppressed, and the gas sealing function of the solid electrolyte membrane 40 is reduced. Can be suppressed.

  An air electrode 60 is formed on the upper surface of a portion in contact with each fuel electrode active part 22 in the solid electrolyte membrane 40 via a reaction preventing film 50. The reaction preventing film 50 is a fired body made of a dense material, and the air electrode 60 is a fired body made of a porous material having electron conductivity. The shape of the reaction preventing film 50 and the air electrode 60 viewed from above is substantially the same rectangle as the fuel electrode active part 22.

The reaction preventing film 50 can be made of, for example, GDC = (Ce, Gd) O ₂ (gadolinium-doped ceria). The thickness of the reaction preventing film 50 is 3 to 50 μm. The air electrode 60 can be made of, for example, LSCF = (La, Sr) (Co, Fe) O ₃ (lanthanum strontium cobalt ferrite). Alternatively, from LSF = (La, Sr) FeO ₃ (lanthanum strontium ferrite), LNF = La (Ni, Fe) O ₃ (lanthanum nickel ferrite), LSC = (La, Sr) CoO ₃ (lanthanum strontium cobaltite), etc. It may be configured. Further, the air electrode 60 may be configured by two layers of a first layer (inner layer) made of LSCF and a second layer (outer layer) made of LSC. The thickness of the air electrode 60 is 10 to 100 μm.

  The reaction preventing film 50 is interposed because the YSZ in the solid electrolyte film 40 and the Sr in the air electrode 60 react with each other in the SOFC during the production or operation of the SOFC, and the solid electrolyte film 40 and the air electrode. This is to suppress the occurrence of a phenomenon in which a reaction layer having a large electric resistance is formed at the interface with the substrate 60.

  Here, the laminated body formed by laminating the fuel electrode 20, the solid electrolyte membrane 40, the reaction preventing membrane 50, and the air electrode 60 corresponds to the “power generation element portion A” (see FIG. 2). In other words, a plurality (four in this example) of power generating element portions A are arranged on the upper surface of the support substrate 10 at a predetermined interval in the longitudinal direction.

  For each pair of adjacent power generation element portions A and A, the air electrode 60 of one power generation element portion A (on the left side in FIG. 2) and the interconnector of the other power generation element portion A (on the right side in FIG. 2). The air electrode current collecting film 70 is formed on the upper surfaces of the air electrode 60, the solid electrolyte film 40, and the interconnector 30. The air electrode current collector film 70 is a fired body made of a porous material having electron conductivity. The shape of the air electrode current collector film 70 as viewed from above is a rectangle.

The air electrode current collector film 70 can be made of, for example, LSCF = (La, Sr) (Co, Fe) O ₃ (lanthanum strontium cobalt ferrite). Alternatively, LSC = (La, Sr) CoO ₃ (lanthanum strontium cobaltite) may be used. Or you may comprise from Ag (silver) and Ag-Pd (silver palladium alloy). The thickness of the air electrode current collector film 70 is 50 to 500 μm.

  By forming each air electrode current collecting film 70 in this way, for each pair of adjacent power generation element portions A and A, the air electrode 60 of one power generation element portion A (on the left side in FIG. 2), The other fuel electrode 20 (particularly, the fuel electrode current collector 21) of the power generating element part A (on the right side in FIG. 2) passes through the “air electrode current collector film 70 and interconnector 30” having electronic conductivity. Are electrically connected. As a result, a plurality (four in this example) of power generation element portions A arranged on the upper surface of the support substrate 10 are electrically connected in series. Here, the “air electrode current collector film 70 and the interconnector 30” having electronic conductivity correspond to “electrical connection portions”.

  The interconnector 30 corresponds to the “first portion made of a dense material” in the “electrical connection portion” and has a porosity of 10% or less. The air electrode current collecting film 70 corresponds to the “second portion made of a porous material” in the “electrical connection portion”, and has a porosity of 20 to 60%.

As described above, the “horizontal stripe type” SOFC structure described above has a fuel gas (in the same direction) in the fuel gas flow path 11 of the support substrate 10 as shown in FIG. Hydrogen gas or the like is allowed to flow, and the upper and lower surfaces of the support substrate 10 (in particular, each air electrode current collector film 70) are exposed to “gas containing oxygen” (air or the like) (or along the upper and lower surfaces of the support substrate 10). By flowing a gas containing oxygen), an electromotive force is generated due to an oxygen partial pressure difference generated between both side surfaces of the solid electrolyte membrane 40. Furthermore, when this structure is connected to an external load, chemical reactions shown in the following formulas (1) and (2) occur, and current flows (power generation state).
(1/2) · O ₂ + 2e ⁻ → O ²⁻ (where: air electrode 60) (1)
H ₂ + O ²⁻ → H ₂ O + 2e ⁻
(At: Fuel electrode 20) (2)

  In the power generation state, as shown in FIG. 5, a current flows as indicated by an arrow in each pair of adjacent power generation element portions A and A. As a result, as shown in FIG. 4, the SOFC structure as a whole (specifically, the interconnector 30 of the power generating element part A on the frontmost side in FIG. 4 and the air electrode of the power generating element part A on the innermost side in FIG. The power is extracted (via 60).

(Production method)
Next, an example of a manufacturing method of the “horizontal stripe type” SOFC structure shown in FIG. 1 will be briefly described with reference to FIGS. 6 to 14, “g” at the end of the reference numeral of each member represents that the member is “before firing”.

  First, a support substrate molded body 10g having the shape shown in FIG. 6 is produced. The molded body 10g of the support substrate is manufactured by using a method such as extrusion molding or cutting using a slurry obtained by adding a binder or the like to the material of the support substrate 10 (for example, CSZ). obtain. Hereinafter, the description will be continued with reference to FIGS. 7 to 14 showing partial cross sections corresponding to line 7-7 shown in FIG. 6.

  When the support substrate molded body 10g is manufactured as shown in FIG. 7, the fuel electrode current collector is then placed in each recess formed in the upper and lower surfaces of the support substrate molded body 10g as shown in FIG. Each of the molded parts 21g is embedded and formed. Next, as shown in FIG. 9, a molded body 22g of the fuel electrode active portion is embedded and formed in each recess formed in the outer surface of the molded body 21g of each fuel electrode current collector. The molded body 21g of each fuel electrode current collector and each of the fuel electrode active parts 22g use, for example, a slurry obtained by adding a binder or the like to the powder of the material of the fuel electrode 20 (for example, Ni and YSZ), It is embedded and formed using printing methods.

Subsequently, as shown in FIG. 10, in each concave portion formed in “the portion excluding the portion where the molded body 22 g of the fuel electrode active portion is embedded” on the outer surface of the molded body 21 g of each fuel electrode current collector. The interconnector molded bodies 30g are respectively embedded and formed. The molded body 30g of each interconnector is embedded and formed by using a slurry obtained by adding a binder or the like to the material of the interconnector 30 (for example, LaCrO ₃ ), using a printing method or the like. .

  Next, as shown in FIG. 11, the outer periphery extending in the longitudinal direction of the molded body 10g of the support substrate in a state in which the molded body (21g + 22g) of the plurality of fuel electrodes and the molded body 30g of the plurality of interconnectors are respectively embedded and formed. A solid electrolyte membrane molded film 40g is formed on the entire surface excluding the central portion in the longitudinal direction of each portion where the plurality of interconnector molded bodies 30g are formed. The molded membrane 40g of the solid electrolyte membrane is formed using, for example, a printing method, a dipping method, etc., using a slurry obtained by adding a binder or the like to the powder of the material of the solid electrolyte membrane 40 (for example, YSZ). The

  Next, as shown in FIG. 12, a reaction prevention film molding film 50g is formed on the outer surface of the solid electrolyte membrane molding body 40g in contact with the fuel electrode molding body 22g. The molded film 50g of each reaction preventing film is formed using a slurry obtained by adding a binder or the like to the powder of the material (for example, GDC) of the reaction preventing film 50, using a printing method or the like.

  Then, 10 g of the support substrate molded body in which various molded films are thus formed is fired in air at 1500 ° C. for 3 hours. As a result, a structure in which the air electrode 60 and the air electrode current collector film 70 are not formed in the SOFC structure shown in FIG. 1 is obtained.

  Next, as shown in FIG. 13, an air electrode forming film 60 g is formed on the outer surface of each reaction preventing film 50. The molded film 60g of each air electrode is formed using a slurry obtained by adding a binder or the like to the powder of the material of the air electrode 60 (for example, LSCF), using a printing method or the like.

  Next, as shown in FIG. 14, for each pair of adjacent power generation element portions, air is formed so as to straddle the air electrode molding film 60 g of one power generation element portion and the interconnector 30 of the other power generation element portion. On the outer surface of the electrode forming film 60 g, the solid electrolyte film 40, and the interconnector 30, the air electrode current collecting film forming film 70 g is formed. The forming film 70g of each air electrode current collector film is obtained by using a slurry obtained by adding a binder or the like to the powder of the material of the air electrode current collector film 70 (for example, LSCF), using a printing method or the like. It is formed.

  Then, the support substrate 10 in which the molded films 60g and 70g are thus formed is baked in air at 1050 ° C. for 3 hours. As a result, the SOFC structure shown in FIG. 1 is obtained. The example of the method for manufacturing the SOFC structure shown in FIG. 1 has been described above.

  At this time, the Ni component in the support substrate 10 and the fuel electrode 20 is NiO by firing in an oxygen-containing atmosphere. Therefore, in order to acquire the conductivity of the fuel electrode 20, thereafter, reducing fuel gas is flowed from the support substrate 10 side, and NiO is reduced at 800 to 1000 ° C. for 1 to 10 hours. This reduction process may be performed during power generation.

(Detailed shape of the end surface of the support substrate on the gas discharge side)
Next, the detailed shape of the end surface of the support substrate 10 on the gas discharge side will be described with reference to FIGS. The “end face” on the gas discharge side of the support substrate 10 is “visible” on the gas discharge side end portion of the support substrate 10 when the support substrate 10 is viewed from the gas discharge side (downstream side of the gas) along the longitudinal direction. Refers to "region".

  As shown in FIG. 15, the end surface on the gas discharge side of the support substrate 10 has a planar shape as a whole. On the other hand, as shown in FIG. 16, the end surface of the support substrate 10 on the gas discharge side as a whole is “the central portion in the width direction (y-axis direction) is the downstream side of the gas in the longitudinal direction (x-axis negative direction). A convex shape protruding to the side). In other words, the center portion in the width direction of the end surface on the gas discharge side of the support substrate 10 may protrude toward the downstream side of the gas in the longitudinal direction as compared with both end portions of the end surface in the width direction.

  In other words, “the center position in the width direction” (see the point A in FIG. 16) on the end surface of the support substrate 10 on the gas discharge side is “at the ends in the width direction of the plurality of fuel gas flow paths 11 on the end surface”. Compared to the position of the corresponding endmost portion in the width direction in each opening on the gas discharge side of the two flow paths 11 (see point B in FIG. 16), on the downstream side of the gas in the longitudinal direction. May be located. Further, for each opening on the gas discharge side of the “two fuel gas passages 11 positioned at both ends in the width direction”, “the position of the most central portion in the width direction” in the opening (point of FIG. 16). C) may be located on the downstream side of the gas in the longitudinal direction as compared to “the position of the corresponding endmost portion in the width direction” in the opening (see point B in FIG. 16). .

  Thus, in the configuration in which the end surface on the gas discharge side of the support substrate 10 is convex, the end surface on the gas discharge side of the support substrate 10 is cracked compared to the configuration in which the shape of the end surface is flat. It has been found that the situation in which it occurs is easily suppressed. Although the details are unknown, when the end surface on the gas discharge side of the support substrate 10 has a convex shape, the support substrate 10 has an overall shape that is planar. The temperature distribution of the gas discharge side end when the gas burns at the gas discharge side end changes, and the gas discharge side end (particularly, two fuel gas flow paths 11 located at both ends in the width direction). This is considered to be because it is difficult to generate excessive thermal stress locally in the vicinity of the opening on the gas discharge side.

  In the example shown in FIG. 16, the end surface on the gas discharge side of the support substrate 10 has a curved surface shape (convex shape) in the entire width direction. However, as shown in FIG. The shape which a plane part exists may be exhibited. Note that points A, B, and C in FIG. 17 correspond to points A, B, and C in FIG. 16, respectively.

  Further, as can be understood from FIGS. 19 and 20 which are 19-19 cross section and 20-20 cross section of FIG. 18, “the main surface or side end surface of the support substrate 10 and the fuel gas in the end surface on the gas discharge side of the support substrate 10”. The “portion between the flow paths 11” (see E1 in FIGS. 19 and 20) does not have a flat portion and has a convex shape that protrudes downstream of the gas in the longitudinal direction. Here, E1 in FIG. 19 corresponds to “a portion between the side end surface of the support substrate 10 and the fuel gas flow path 11” on the end surface of the support substrate 10 on the gas discharge side, and E1 in FIG. 10 corresponds to the “portion between the main surface of the support substrate 10 and the fuel gas flow path 11” on the end face on the gas discharge side.

  In addition, the “portion between adjacent fuel gas passages 11, 11” (see E 2 in FIG. 19) on the end surface of the support substrate 10 on the gas discharge side does not have a flat portion and is gas in the longitudinal direction. It has a convex shape protruding to the downstream side.

  In other words, the longitudinal direction of “the portion between the main surface or side end surface of the support substrate 10 and the fuel gas flow path 11” in the support substrate 10 (refer to the hatched region corresponding to E1 in FIGS. 19 and 20). The end face on the gas downstream side (end face on the x-axis negative direction side, see E1 in FIGS. 19 and 20) does not have a flat portion and has a convex shape that protrudes downstream of the gas in the longitudinal direction. Yes. In addition, the end face of the gas downstream side in the longitudinal direction of the “portion between adjacent fuel gas passages 11, 11” (see the hatched region corresponding to E 2 in FIG. 19) in the support substrate 10 (the negative x-axis direction) The end face on the side (see E2 in FIG. 19) does not have a flat portion and has a convex shape protruding in the longitudinal direction to the downstream side of the gas. Note that points A, B, and C in FIG. 18 correspond to points A, B, and C in FIG. 16, respectively.

  Thus, when the support substrate 10 is viewed from the gas discharge side (downstream side of the gas) along the longitudinal direction, “the main surface or side end surface of the support substrate 10 and the fuel gas flow at the end surface of the support substrate 10 on the gas discharge side”. A portion connecting with the path 11 (see E1 in FIGS. 19 and 20) does not have a flat portion, and has a convex shape protruding in the longitudinal direction to the downstream side of the gas. In addition, when the support substrate 10 is viewed from the gas discharge side (downstream side of the gas) along the longitudinal direction, “the portion connecting the adjacent fuel gas flow paths 11, 11” on the end surface of the support substrate 10 on the gas discharge side. (Refer to E2 in FIG. 19) does not have a flat portion, and has a convex shape protruding in the longitudinal direction to the downstream side of the gas. As a result, the same part has a planar configuration, or a convex surface projecting in the longitudinal direction on the downstream side of the gas and a flat portion (for example, see FIG. 21). In comparison, it has been found that the occurrence of cracks at the gas discharge side end of the support substrate 10 can be suppressed.

  Although details are unknown, when the end surface on the gas discharge side of the support substrate 10 does not include a flat surface portion, the end surface of the support substrate 10 has a flat surface portion. This is considered to be due to the fact that the thermal stress distribution at the end of the gas discharge side changes when the gas burns, and the concentration of thermal stress is less likely to occur at the end of the gas discharge side.

  Here, the portion “provided with a convex shape that does not have a flat portion and projects to the downstream side of the gas in the longitudinal direction” is the “main surface or side end surface of the support substrate 10” in the end surface on the gas discharge side of the support substrate 10. Or part of the portion between the fuel gas passage 11 and the fuel gas flow path 11 (see E1 in FIGS. 19 to 21), or the end face on the gas discharge side of the support substrate 10. It may be a part of the portion between the adjacent fuel gas flow paths 11 and 11 (see E2 in FIGS. 19 and 21) or the whole. It is preferable that the entire region of the end surface on the gas discharge side of the support substrate 10 does not have a flat portion and has a convex shape protruding in the longitudinal direction to the downstream side of the gas.

  Note that a coating film (for example, a YSZ film) may be formed on the end surface of the support substrate 10 on the gas discharge side for the purpose of preventing reoxidation of Ni inside the support substrate 10. In this case, the “end surface composed of the material of the support substrate” (that is, the surface covered with the coating film, not the surface of the coating film) in the end surface portion on the gas discharge side of the support substrate 10 is shown in FIGS. It is necessary to have the shape shown in.

  In addition, this invention is not limited to the said embodiment, A various modification can be employ | adopted within the scope of the present invention. For example, in the above embodiment, the shape shown in FIG. 15 to FIG. 21 is used for the end surface of the support substrate 10 on the gas discharge side (downstream side of the gas). As for the end face on the upstream side, a shape corresponding to the shape shown in FIGS. 15 to 21 may be adopted.

  Moreover, in the said embodiment, although the several recessed part 12 is formed in each of the upper and lower surfaces of the flat support substrate 10, and the several electric power generation element part A is provided, as shown in FIG. A plurality of recesses 12 may be formed only on one side of the power generation element A and a plurality of power generation element portions A may be provided.

  Further, in the above embodiment, the fuel electrode 20 is composed of two layers of the fuel electrode current collector 21 and the fuel electrode active portion 22, but the fuel electrode 20 is a single layer corresponding to the fuel electrode active portion 22. It may be configured.

  In addition, in the above embodiment, as shown in FIG. 3, the recess 21 b formed on the outer surface of the anode current collector 21 has a bottom wall made of the material of the anode current collector 21 and the circumferential direction. It is a rectangular parallelepiped depression defined by closed side walls (two side walls along the longitudinal direction made of the material of the support substrate 10 and two side walls along the width direction made of the material of the fuel electrode current collector 21). ing. As a result, the two side surfaces and the bottom surface along the width direction of the interconnector 30 embedded in the recess 21b are in contact with the fuel electrode current collector 21 in the recess 21b.

  On the other hand, as shown in FIG. 23, the recess 21b formed on the outer surface of the fuel electrode current collector 21 has a bottom wall made of the material of the fuel electrode current collector 21 and the fuel electrode current collector over the entire circumference. It may be a rectangular parallelepiped recess defined by circumferentially closed side walls (two side walls along the longitudinal direction and two side walls along the width direction) made of the material of the electric part 21. Similarly, a recess 21a formed on the outer surface of the fuel electrode current collector 21 has a bottom wall made of the material of the fuel electrode current collector 21 and a circumference made of the material of the fuel electrode current collector 21 over the entire circumference. It may be a rectangular parallelepiped depression defined by side walls closed in the direction (two side walls along the longitudinal direction and two side walls along the width direction).

  According to this, all four side surfaces and the bottom surface of the interconnector 30 embedded in the recess 21b are in contact with the fuel electrode current collector 21 in the recess 21b. Therefore, the area of the interface between the fuel electrode current collector 21 and the interconnector 30 can be further increased. Therefore, the electronic conductivity between the fuel electrode current collector 21 and the interconnector 30 can be further increased, and as a result, the power generation output of the fuel cell can be further increased. Similarly, all four side surfaces and the bottom surface of the anode active portion 22 embedded in the recess 21a are in contact with the anode current collector 21 in the recess 21a. Therefore, the area of the interface between the fuel electrode current collector 21 and the fuel electrode active part 22 can be further increased. Therefore, the electron conductivity between the fuel electrode current collector 21 and the fuel electrode active part 22 can be further increased, and as a result, the power generation output of the fuel cell can be further increased.

  Further, in the above-described embodiment, a so-called “horizontal stripe type” configuration in which a plurality of power generation element portions A electrically connected in series to the main surface of the support substrate 10 is employed is employed. A so-called “vertical stripe type” configuration in which a plurality of cells each provided with only one power generation element portion on the main surface 10 may be stacked.

  DESCRIPTION OF SYMBOLS 10 ... Support substrate, 11 ... Fuel gas flow path, 20 ... Fuel electrode, 40 ... Solid electrolyte membrane, 60 ... Air electrode, A ... Power generation element part

Claims (2)

A flat porous support substrate having a longitudinal direction, in which a plurality of gas passages each penetrating in the longitudinal direction are formed at intervals in the width direction; and
A power generation element portion provided on the main surface of the support substrate, wherein at least a fuel electrode, a solid electrolyte, and an air electrode are laminated in this order;
A fuel cell that is a fired body comprising:
One end side and the other end side in the longitudinal direction of each gas flow path correspond to a gas inflow side and a gas discharge side, respectively.
A portion between the main surface or side end surface of the support substrate and the gas flow path in the end surface on the other end side in the longitudinal direction of the support substrate does not include a flat portion, and the other end in the longitudinal direction. A fuel cell having a convex shape protruding to the side. The fuel cell according to claim 1, wherein
The portion between the adjacent gas flow paths on the end surface on the other end side in the longitudinal direction of the support substrate does not have a flat portion and has a convex shape protruding to the other end side in the longitudinal direction. A fuel cell.

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