JP2012009226A - Horizontal-stripe solid oxide type fuel battery cell stack, horizontal-stripe solid oxide type fuel battery bundle and fuel battery - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cell stack having an end portion on the exhaust side of a first reactant gas which is less prone to being destroyed even if a heat cycle is executed repeatedly, or the first reactant gas exhausted from a first reactant gas outlet is burnt, and to provide a cell bundle and a fuel battery.SOLUTION: The cell stack includes: an electrically insulative porous supporting body 2 having a gas passage for forcing a first reactant gas to flow along its longitudinal direction therein, a first reactant gas inlet 5a of the gas passage on the side of one end thereof and a first reactant gas outlet 5b of the gas passage on the side of the other end; a plurality of fuel battery cells 3 arrayed on a portion of the porous supporting body 2 except at least a portion at the other end along the longitudinal direction of the porous supporting body and generating electric power using the first and second reactant gases supplied through the porous supporting body; a solid electrolyte coating 4a provided at least partially on the other end portion of the porous supporting body; and a glass coating 4b provided on the solid electrolyte coating.

Description

  The present invention relates to a horizontal stripe-type solid oxide fuel cell stack (hereinafter sometimes simply referred to as a cell stack), a horizontal stripe-type solid oxide fuel cell bundle (hereinafter sometimes simply referred to as a bundle), and a fuel cell. .

  In recent years, fuel cells have attracted attention as a power generation method having high power generation efficiency in which the number of energy conversion stages is reduced and chemical energy is directly converted into electric energy. In particular, a solid oxide fuel cell has a high power generation temperature of 600 ° C. to 1000 ° C. and a low internal resistance in the fuel cell, so that it has the highest power generation efficiency among the fuel cells, and further uses residual fuel for gas. It can be used as a heat source for further power generation by a turbine or cogeneration, and has the property of converting chemical energy into electrical energy with high conversion efficiency. In particular, the horizontal stripe solid oxide fuel cell can obtain a high voltage with a small number of cell stacks, but needs to be a cell stack resistant to thermal stress caused by a heat cycle between room temperature and a high operating temperature.

  A conventional cell stack includes a gas flow path for flowing a fuel gas along the longitudinal direction of the porous support (hereinafter sometimes simply referred to as the longitudinal direction), and the fuel in the gas flow path on one end side. A fuel electrode layer, a solid electrolyte layer, and an air electrode layer are laminated in this order on an electrically insulating porous support that has a gas inlet and a fuel gas outlet on the other end. A plurality of multilayered fuel cells are provided.

  In such a cell stack, there is a problem that the vicinity of the fuel gas discharge port on the other end side may be destroyed by the repetition of the above heat cycle. For example, in order to shorten the start-up time until power generation, an operation (heat cycle) in which the temperature is suddenly heated to around 900 ° C. and lowered to room temperature is repeated, or the fuel gas discharged from the fuel gas discharge port is burned If the operation (heat cycle) for stopping the supply of fuel gas and lowering the temperature to room temperature is repeated, the vicinity of the fuel gas discharge port may be destroyed at an early stage.

In order to solve such a problem, Patent Document 1 proposes chamfering the corner of the end surface of the porous support on the fuel gas discharge side.
Patent Document 2 proposes impregnating a porous support around a fuel gas discharge port with an inorganic component mainly composed of zirconia.

Further, in Patent Document 3, in order to prevent oxidative expansion due to an oxygen-containing gas, Y ₂ O _{3 is provided} on the end surface on the fuel gas discharge side and the inner surface of the fuel gas flow path in the porous support near the fuel gas discharge port. It has been proposed to form a dense inorganic coating film such as ZrO ₂ (hereinafter sometimes referred to as YSZ) in which is dissolved.

JP 2004-234969 A JP 2004-259604 A JP 2006-59789 A

  However, in the fuel cells described in Patent Documents 1 to 3, the end on the fuel gas discharge side is damaged by the repetition of the heat cycle as described above (specifically, the crack extends in the longitudinal direction and the vertical crack occurs). There is a problem that the end portion is easily broken.

  Therefore, according to the present invention, when the heat cycle is repeated or when the first reaction gas discharged from the first reaction gas discharge port is burned, the end on the first reaction gas discharge side is not easily destroyed. It aims at providing a cell stack, a bundle, and a fuel cell.

  As described above, the inventors of the present invention, in the process of earnestly researching to solve the above-mentioned problem, destroy the end portion on the first reaction gas discharge side by the heat cycle. I suspected that the strength was insufficient. Moreover, it was estimated that the difference in thermal expansion coefficient between the porous support and the solid electrolyte coating also promoted the thermal stress. Therefore, the present inventors provide a solid electrolyte coating on at least a part of the other end side of the porous support, and by providing a glass coating on the solid electrolyte coating, when repeating the heat cycle, In the case where the first reaction gas discharged from the first reaction gas discharge port is burned, it is found that the end of the first reaction gas discharge side is less likely to be destroyed, and the present invention is completed. It came.

That is, the present invention has the following configuration.
(1) A gas flow path for flowing a first reaction gas along the longitudinal direction is provided inside, the first reaction gas inlet of the gas flow path is provided on one end side, and the gas is provided on the other end side. An inner electrode layer, a solid electrolyte layer, and an outer electrode layer are laminated in this order on at least the other end portion on the electrically insulating porous support having the first reaction gas discharge port of the flow path. A plurality of fuel cells arranged along the longitudinal direction of the porous support, and the fuel cells are supplied to the inner electrode layer via the porous support. And a second reactive gas supplied to the outer electrode layer, a horizontal stripe solid oxide fuel cell stack that generates power, and at least a part of the other end of the porous support Is provided with a solid electrolyte coating, and a glass coating is provided on the solid electrolyte coating. Segmented-in-series solid oxide fuel cell stack, characterized by being.
(2) The inner electrode layer is a fuel electrode layer, the outer electrode layer is an air electrode layer, the first reaction gas is a fuel gas, and the second reaction gas is an oxygen-containing gas. The horizontal stripe solid oxide fuel cell stack according to (1) above.
(3) The (1) or the above, wherein the solid electrolyte coating and the glass coating are provided on an outer peripheral surface, an end surface and an inner surface of the gas flow path at the other end of the porous support. The horizontally-striped solid oxide fuel cell stack according to (2).
(4) The solid electrolyte coating and the glass coating are provided on the chamfered portion formed by chamfering the outer peripheral corner at the other end of the porous support. The horizontally-striped solid oxide fuel cell stack according to any one of the above.
(5) A gas manifold for supplying the reaction gas to the gas flow path at one end of the plurality of horizontal stripe solid oxide fuel cell stacks according to any one of (1) to (4) A horizontally-striped solid oxide fuel cell bundle characterized by being fixed to
(6) A fuel cell comprising a plurality of horizontally-striped solid oxide fuel cell bundles according to claim 5 housed in a housing container.

  In the cell stack of the present invention, when the heat cycle is repeated or when the first reaction gas discharged from the first reaction gas discharge port is burned, the end on the first reaction gas discharge side is destroyed. It is difficult to improve durability and reliability. Furthermore, a bundle and a fuel cell with high long-term reliability using the cell stack of the present invention can be provided.

It is a perspective view which fractures | ruptures and shows a part of horizontal stripe type solid oxide fuel cell stack concerning one Embodiment of this invention. It is a schematic sectional drawing of the cell stack shown in FIG. It is a longitudinal cross-sectional view which shows the porous support body molded object concerning one Embodiment of this invention. (A)-(h) is process drawing which shows the manufacturing method of the cell stack concerning one Embodiment of this invention. It is the schematic which shows one Embodiment of the bundle of this invention.

  Hereinafter, one embodiment of a cell stack, a bundle, and a fuel cell of the present invention will be described in detail with reference to the drawings.

(Cell stack 1)
The cell stack 1 shown in FIG. 1 and FIG. 2 is a fuel cell unit at a predetermined interval along the longitudinal direction on the front and back surfaces of the porous support 2 at a portion excluding at least the other end on the porous support 2. This is called a horizontal stripe type solid oxide fuel cell in which a plurality of 3 are arranged, and a reinforcing coating 4 is formed on at least a part of the other end of the porous support 2 (see FIG. 2).

Hereinafter, materials and the like of each member constituting the cell stack 1 will be described in detail.
(Porous support 2)
The shape of the porous support 2 is not particularly limited, but is preferably a flat plate from the viewpoint of improving the power generation performance of the cell stack, and a gas flow for flowing the first reaction gas along the longitudinal direction. The passage 5 is provided inside, has a first reaction gas introduction port 5a (hereinafter sometimes referred to as an introduction port 5a) of the gas flow channel 5 on one end side, and the first reaction gas introduction port 5a on the other end side. Reaction gas discharge port 5b (hereinafter sometimes referred to as discharge port 5b).
The gas flow path 5 may be formed with a plurality of gas flow paths 5 in parallel in the width direction of the porous support 2, and in such a case, the number of the gas flow paths 5 is 3 to 20, preferably 6 to Seventeen. In this way, by forming a plurality of gas flow paths 5 inside the porous support 2, the porous support 2 is compared with the case where one large gas flow path is formed inside the porous support 2. Can be made into a flat plate shape, and the area of the fuel cell 3 per volume of the cell stack 1 can be increased to increase the amount of power generation. Therefore, for example, when the bundle 20 is configured in order to obtain a necessary power generation amount (see FIG. 5), the number of cell stacks 1 can be reduced.
Further, it is preferable that the outer peripheral corner portion of the end face on the first reaction gas discharge side of the porous support 2 is subjected to chamfering such as C surface shape, R surface shape, etc. Is preferably applied. The chamfered portion is a chamfered portion 2a (see FIG. 2).

(Material of porous support 2)
The constituent material of the porous support 2 must be electrically insulating. For example, MgO, Ni or Ni oxide (NiO) (hereinafter sometimes referred to as Ni), rare earth element oxide, and the like. Formed from. Examples of the rare earth element constituting the rare earth element oxide include Y, Lb, Yb, Tm, Er, Ho, Dy, Gd, Sm, and Pr. Examples of the rare earth element oxide include Y ₂ O _3. And Yb ₂ O _3, and Y ₂ O ₃ is particularly preferable. MgO is 70 to 80% by volume, rare earth element oxide is 10 to 20% by volume, Ni and the like (NiO is usually reduced by hydrogen gas and present as Ni during power generation) is 10 to 25% by volume in terms of NiO, It is good to contain in the porous support body 2 in the range of 15-20 volume% especially so that it may become 100 volume% as a total amount. The thermal expansion coefficient of the porous support 2 is usually about 10.5 to 12.5 × 10 ⁻⁶ (1 / K).

The porous support 2 needs to be electrically insulating in order to prevent an electrical short circuit between the fuel cells 3, and usually has a resistivity of 10 ⁵ Ω · cm or more. When the content of Ni or the like exceeds the above range, the electric resistance value tends to decrease. The porous support 2 is porous because the gas in the gas flow path 5 must be able to be introduced to the fuel cell 3 side. The porous support 2 has a porosity of 25% or more, particularly 30 to 40%. It is preferable that it exists in the range.

(Fuel battery cell 3)
Each fuel battery cell 3 shown in FIG. 2 is configured by laminating an inner electrode layer 3a, a solid electrolyte layer 3b, and an outer electrode layer 3c in this order on a porous support 2. The adjacent fuel cell 3 is connected to the interconnector 3d stacked on the inner electrode layer 3a of one adjacent fuel cell 3 and the cell connection stacked on the outer electrode layer 3c of the other adjacent fuel cell 3. The inner electrode layer 3a of one adjacent fuel cell 3 and the outer electrode layer 3c of the other adjacent fuel cell 3 are electrically connected in series via the member 3e.

The fuel cell 3 preferably has the inner electrode layer 3a as a fuel electrode layer and the outer electrode layer 3c as an air electrode layer from the viewpoint of mass productivity and mechanical reliability. The gas is a fuel gas, and the second reaction gas described later is an oxygen-containing gas.
In addition, the fuel cell 3 can be configured such that the inner electrode layer 3a is an air electrode layer and the outer electrode layer 3c is a fuel electrode layer. In such a case, the first reaction gas described later is an oxygen-containing gas, A second reactive gas described later is a fuel gas. In the following description, a description will be given using a cell stack of a type having a configuration in which the inner electrode layer 3a is a fuel electrode layer and the outer electrode layer 3c is an air electrode layer.

  By flowing a fuel gas containing hydrogen into the gas flow path 5 of the porous support 2 and exposing the air electrode layer to an oxygen-containing gas containing oxygen such as air, the following formula ( The electrode reactions shown in i) and (ii) occur, a potential difference is generated between the two electrodes, and power is generated.

(Material of solid electrolyte layer 3b)
The solid electrolyte layer 3b conducts oxygen ions generated by the electrode reaction of the formula (i) to the fuel electrode layer, and needs to have a property of high oxygen ion conductivity and low electronic conductivity. It is formed from an oxide having a high conductivity. For example, the solid electrolyte layer 3b is formed from a dense ceramic containing stabilized ZrO ₂ composed of ZrO ₂ which was a solid solution of a rare earth element or its oxide.
Here, as rare earth elements to be dissolved or oxides thereof, for example, Sc, Y, La, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, etc. Or oxides thereof, and the like, preferably Y, Yb, or oxides thereof. The solid electrolyte layer 3b is made of lanthanum gallate (LaGaO) having a thermal expansion coefficient substantially equal to that of stabilized ZrO ₂ (8 mol% Yttria Stabilized Zirconia, hereinafter referred to as “8YSZ”) in which 8 mol% of Y is dissolved. ₍₃ ) A solid electrolyte layer can also be used. The solid electrolyte layer 3b has a thickness of 10 to 100 μm, for example, and has a relative density (according to Archimedes method) of 93% or more, preferably 95% or more.
The solid electrolyte layer 3b has a function as an electrolyte that bridges electrons between electrodes, and at the same time, leaks of fuel gas (first reaction gas) or oxygen-containing gas (second reaction gas) (gas permeation). ) To prevent gas).

(Fuel electrode layer material)
The fuel electrode layer causes the electrode reaction of the above formula (ii) and is formed of a porous conductive ceramic known per se. For example, it is composed of ZrO ₂ (stabilized zirconia) in which a rare earth element is solid solution and Ni or the like. As the stabilized zirconia in which the rare earth element is dissolved, the material of the solid electrolyte layer 3b can be used.

The stabilized zirconia content in the fuel electrode layer is 35 to 65% by volume, preferably 45 to 55% by volume, and the content of Ni or the like is 65 to 65% in terms of NiO in order to exhibit good power generation performance. It should be in the range of 35% by volume, preferably 45-55% by volume.
The open porosity of the fuel electrode layer is preferably 15% or more, particularly in the range of 20 to 40%.
Furthermore, the thickness of the fuel electrode layer is in the range of 5 to 230 μm from the viewpoint of absorbing thermal stress generated due to the difference in thermal expansion from the solid electrolyte layer 3b and preventing cracking or peeling of the fuel electrode layer. It is desirable to be.

The fuel electrode layer includes an active fuel electrode layer on the solid electrolyte layer 3b side, a porous support 2 side (when the inner electrode layer 3a is a fuel electrode layer), or the outside of the cell stack 2 (the outer electrode layer 3c is The fuel electrode layer can be configured in a two-layer structure with the current collecting fuel electrode layer.
The active fuel electrode layer may be the same as the material of the fuel electrode layer described above, and the current collecting fuel electrode layer may be composed of the same material as the fuel electrode layer. The active fuel electrode layer and the current collecting fuel electrode layer can have different contents of Ni and the like.
In this case, it is preferable that an interconnector 3d to be described later is disposed on one end side on the current collecting fuel electrode layer, and the active fuel electrode layer is disposed on the current collecting fuel electrode layer with a distance from the interconnector 3d.
The thickness of the active fuel electrode layer is in the range of 5 to 30 μm from the viewpoint of absorbing thermal stress generated due to the difference in thermal expansion from the solid electrolyte layer 3b and preventing cracking or peeling of the fuel electrode layer. It is preferable that it exists in.

(Current collecting fuel electrode layer)
Ni or the like contained in the current collecting fuel electrode layer is 30 to 60% by volume, preferably 45 to 55% by volume in terms of NiO, and the rare earth element oxide content is 40 to 70% by volume, preferably 45%. It is in the range of ~ 55% by volume. The current collecting fuel electrode layer needs to be conductive so as not to impair the flow of current, and it is generally desirable that the current collecting fuel electrode layer have a conductivity of 400 S / cm or more. From the viewpoint of having good electrical conductivity, the content of Ni or the like is desirably 30% by volume or more.
Further, the thickness of the current collecting fuel electrode layer is preferably 80 to 200 μm from the viewpoint of improving electric conductivity.

  As described above, the active fuel electrode layer on the solid electrolyte layer 3b side and the porous support 2 side (when the fuel electrode layer is the inner electrode layer 3a) or the outside of the cell stack 2 (the fuel electrode layer is In the case of the structure in which the current collecting fuel electrode layer of the outer electrode layer 3c) is formed in two layers, the content of Ni or the like in terms of NiO in the current collecting fuel electrode layer on the porous support 2 side is 30-60. By adjusting the volume within the range of% by volume, it is possible to reduce the thermal stress caused by the difference in thermal expansion between the cell stack 1 during production, during heating and during cooling. And peeling can be suppressed. For this reason, even in the case where power generation is performed by flowing the first reaction gas, the consistency of the thermal expansion coefficient with the porous support 2 is stably maintained, and cracks due to the difference in thermal expansion can be effectively avoided. .

(Material of air electrode layer)
The air electrode layer causes the electrode reaction of the formula (i) and is formed from conductive ceramics. Examples of the conductive ceramics include ABO ₃ type perovskite type oxides. Examples of such perovskite type oxides include transition metal type perovskite type oxides, preferably LaMnO ₃ type oxides, LaFeO. ₃ based oxide, such as LaCoO ₃ -based oxide, in particular can be mentioned transition metal type perovskite oxide having La at the a site. More preferably, from the viewpoint of high electrical conductivity at about 600 to 1000 ° C., a LaCoO ₃ oxide is used.
In the perovskite oxide described above, La and Sr may coexist at the A site, and Fe, Co, and Mn may coexist at the B site.
The open porosity of the air electrode layer is set to, for example, 20% or more, preferably 30 to 50%. If the open porosity is in the above-described range, the air electrode layer can have good gas permeability.
The thickness of the air electrode layer is set, for example, in the range of 10 to 100 μm, and the air electrode layer can have good power generation performance within the range.

(Material of interconnector 3d)
Since the interconnector 3d is in contact with the first reaction gas and the second reaction gas, the interconnector 3d is formed of conductive ceramics having reduction resistance and oxidation resistance. Examples of conductive ceramics include lanthanum chromite perovskite oxide (LaCrO ₃ oxide).
The conductive ceramic is not dense in order to prevent leakage of the first reaction gas passing through the gas flow path 5 in the porous support 2 and the second reaction gas passing outside the outer electrode layer 3c. For example, it is preferable to have a relative density (Archimedes method) of 93% or more, particularly 95% or more. In addition, a sealing property can also be improved by interposing an appropriate bonding layer (for example, Y ₂ O ₃ ) between the end face of the interconnector 3d and the end face of the solid electrolyte layer 3b.
Further, the interconnector 3d may have a two-layer structure of a metal layer and a metal glass layer containing glass. The metal layer is made of, for example, an alloy of Ag and Ni, and the metal glass layer is made of Ag and glass. Due to the metallic glass layer, the leakage of the first reaction gas that passes through the gas flow path 5 in the porous support 2 to the outside of the cell stack, and the cell stack of the second reaction gas that passes outside the outer electrode layer 3c. Inward leakage can be effectively prevented.

(Material of cell connection member 3e)
The cell connection member 3e is porous. The cell connecting member 3e can be made of a porous material composed of a conductive ceramic (for example, an air electrode layer material) such as LaCoO _{3 and} a noble metal such as Ag—Pd.
When the outer electrode layer 3c is an air electrode layer and the amount of the material of the cell connection member 3e applied to the air electrode layer is small, the material of the cell connection member 3e penetrates into the pores of the air electrode layer, Is not formed. In particular, since noble metals such as Ag-Pd have a small coating amount for cost reduction, the air electrode layer is configured by mixing an air electrode layer material and a current collecting material such as Ag-Pd, and the cell connection member 3e is formed. Not.
On the other hand, when the outer electrode layer 3c is an air electrode layer and a large amount of conductive ceramic such as LaCoO ₃ is applied to the air electrode layer, the cell connection member 3e is formed on the air electrode layer. When the outer electrode layer 3c is an air electrode layer, the air electrode layer may also serve as the cell connection member 3e. In this case, the air electrode layer of the other fuel battery cell 3 adjacent to the interconnector 3d provided on the fuel electrode layer of one fuel battery cell 3 is connected to electrically connect the adjacent fuel battery cells 3 to each other. Can be connected in series. Furthermore, even when the air electrode layer and the interconnector 3d are electrically connected, the cell connection member 3e can be provided on the air electrode layer. In this case, the current flowing in one fuel cell 3 can be efficiently supplied to the other fuel cell 3.

(Arrangement)
The arrangement of the other end side of the cell stack 1 of the fuel battery cell 3 will be described.
On the other end side of the cell stack 1, when the first reaction gas and the second reaction gas discharged from the discharge port 5b are mixed and burned, the influence of the combustion heat is suppressed, In order to suppress the damage of the fuel cell 3 and the like due to the back flow of the second reaction gas flowing outside the gas 1 from the discharge port 5b into the gas flow path 5, as shown in FIGS. It is necessary to arrange the porous support 2 so as to be separated from the end on the first reaction gas discharge side by a predetermined distance.
Hereinafter, a region where the fuel cell 3 is not provided from the other end of the porous support 2 is referred to as a non-power generation region 2b.

(Reinforcing film 4)
As shown in FIG. 2, a solid electrolyte coating 4a is provided on at least a part of the porous support 2 in the non-power generation region 2b, and a reinforcing coating 4 in which a glass coating 4b is provided on the solid electrolyte coating 4a. It is formed.
The solid electrolyte coating 4 a and the glass coating 4 b are preferably provided on the outer peripheral surface, end surface, and inner surface of the gas flow path 5 of the porous support 2 at the other end of the porous support 2.
Moreover, when the corner | angular part of the outer periphery of the end surface at the side of the discharge port 5b of the porous support body 2 is chamfered, the solid electrolyte coating 4a and the glass coating 4b are provided on the formed chamfered portion. Is preferred.
The portion of the solid electrolyte coating 4a formed on the chamfered porous support 2 is a chamfered portion 4c (see FIG. 2), and the portion of the glass coating 4b formed on the chamfered portion 4c is a chamfered portion 4d. Yes (see FIG. 2).

(Chamfer dimension)
The dimension value of the chamfered portion 2a of the porous support 2 is C0.5 mm to C1.0 mm, preferably C0.5 mm to C0.8 mm in the case of the C-face shape. In the case of the R surface shape, it is R0.5 mm to R1.0 mm, preferably R0.5 mm to R0.8 mm.
The dimension value of the chamfered portion 4c of the solid electrolyte coating 4a is C0.5 mm to C1.5 mm, preferably C0.5 mm to C1.2 mm in the case of a C-face shape. In the case of the R surface shape, it is R0.5 mm to R1.5 mm, preferably R0.5 mm to R1.2 mm.
The dimension value of the chamfered portion 4d of the glass coating 4b is C0.8 mm to C2.0 mm, preferably C0.8 mm to C1.5 mm in the case of the C-surface shape. In the case of the R surface shape, it is R0.8 mm to R2.0 mm, preferably R0.8 mm to R1.5 mm.
In the C-plane shape, the angle at which the corners are cut can be set to 30 to 60 °, preferably 30 to 45 ° with respect to the end surface of the porous support 2. In that case, the length of one side to be cut out is the dimension range indicated by the symbol C described above. In addition, the radius of curvature of the R surface shape may not be constant in one chamfered portion, and may be a dimension range indicated by the symbol R.

(Solid electrolyte coating 4a)
The solid electrolyte coating 4a needs to uniformly cover the outside of the porous support 2 in the entire non-power generation region 2b (that is, the entire outer region of the non-power generation region 2b covers the solid electrolyte coating 4a and the solid electrolyte layer 3b. The inner surface of the gas flow path 5 may be covered from the outlet 5b to the inlet 5a in the non-power generation region 2b, and the inner surfaces of all the gas flow paths 5 in the entire non-power generation region 2b may be covered. It is preferable.
The thickness of the solid electrolyte coating 4a may be equal to the thickness of the solid electrolyte layer 3b outside the outer peripheral surface of the end portion of the porous support 2, including the end surface. For example, the thickness is 10 to 100 μm. In the inner surface of the gas flow path 5 of the porous support 2, for example, 7 to 70 μm.

(Material of solid electrolyte coating 4a)
The constituent material of the solid electrolyte coating 4a may be the same as the constituent material of the solid electrolyte layer 3b or the same material as the main component, and a lanthanum gallate material or the like may be used.

(Glass coating 4b)
The glass coating 4b only needs to be provided at least on the solid electrolyte coating 4a. For example, the outer peripheral surface of the end on the solid electrolyte coating 4a, only the end surface or the inner surface of the gas flow path 5, or on the solid electrolyte coating 4a. Both the outer peripheral surface of the end portion and the inner surface of the gas flow channel 5 and both the end surface and the inner surface of the gas flow channel 5 may be provided, but provided on all the solid electrolyte coatings 4a in the entire non-power generation region 2b. It is preferable.
The thickness of the glass coating 4b is, for example, 5 to 20 μm in thickness at the outer peripheral surface of the end portion of the porous support 2 and the outside including the end surface, and the inner surface of the gas flow path 5 of the porous support 2 In, for example, 3 to 12 μm.

(Material of glass coating 4b)
The material of the glass coating. 4b, for example, SiO ₂ -B ₂ O _{3 based, SiO 2 -B 2 O 3 -Al} 2 O 3 _{based, SiO 2 -B 2 O 3 -Al} 2 O 3 - (M) O system (Wherein M represents Ca, Sr, Mg, Ba or Zn), SiO ₂ —Al ₂ O ₃ — (M1) O— (M2) O-based (where M1 and M2 are the same or different and Ca, Sr , Mg, Ba or Zn), SiO ₂ —B ₂ O ₃ —Al ₂ O ₃ — (M1) O— (M2) O (wherein M1 and M2 are the same as above), SiO ₂ — B ₂ O ₃ — (M3) ₂ O system (where M3 represents Li, Na or K), SiO ₂ —B ₂ O ₃ —Al ₂ O ₃ — (M3) ₂ O system (where M3 is the same as above) And Pb-based glass, Bi-based glass, and the like. The material of these glass coat 4b are those containing SiO ₂ or in addition to the mesh-like structure comprising _{Al 2 O 3, K 2 O} , ZnO, BaO, Na 2 O, CaO, or the like, for example, soda glass , Borosilicate glass, quartz glass and the like can be appropriately selected and used.

(Outline of reaction)
In the cell stack 1 of the present invention, the temperature of the cell stack 1 (particularly the temperature of the solid electrolyte layer 3 b) is set to 600 ° C. or higher, the first reaction gas 6 is allowed to flow through the gas flow path 5, and the second It is possible to generate power efficiently by exposing the reaction gas. Furthermore, by forming a bundle 20 described later using a plurality of cell stacks 1 and forming a fuel cell described later using the bundle 20, it is possible to continuously generate high power.

(Cell stack 1 manufacturing method)
Next, a manufacturing method of the cell stack 1 in which the inner electrode layer in the cell stack 1 is a fuel electrode layer (collecting fuel electrode layer and active fuel electrode layer) and the outer electrode layer is an air electrode layer will be described with reference to the drawings. This will be described in detail. FIG. 3 is a longitudinal sectional view showing the porous support body molded body 12 according to the present embodiment. 4A to 4H are process diagrams illustrating a method for manufacturing the cell stack 1 according to the present embodiment.

First, as shown in FIG. 3, the porous support body molded body 12 is produced. As the material of the porous support molded body 12, MgO powder having an average particle diameter (D ₅₀ ) (hereinafter simply referred to as “average particle diameter”) is 0.1 to 10.0 μm, and if necessary, thermal expansion is performed. Ni powder, NiO powder, Y ₂ O ₃ powder, rare earth element-stabilized zirconia powder (YSZ), etc. are used for adjusting the coefficient or improving the bonding strength, and the thermal expansion coefficient is almost equal to the thermal expansion coefficient of the solid electrolyte layer 3b. Mix and mix at a predetermined ratio to match. This mixed powder is mixed with a solvent composed of a pore agent, a cellulosic organic binder, and water, extruded, and formed into a hollow plate having a gas flow path 15 therein, and a flat porous support. The body molded body 12 is prepared and dried, and then calcined at 900 ° C. to 1200 ° C. for 2 to 4 hours. The diameter of the gas flow path 15 is adjusted at the time of extrusion molding. The length of the flat porous support molded body 12 in the longitudinal direction is preferably 250 to 500 mm, and the width in the width direction is preferably 30 to 110 mm.

  When chamfering (for example, C chamfering, R chamfering, etc.) is performed on the outer peripheral corners of the end surface of the porous support body molded body 12 on the first reaction gas discharge side, a luter, sandpaper, or It can be processed using a jig or a surface grinding machine.

Next, each molded body of the inner electrode layer (current collecting fuel electrode layer and active fuel electrode layer), interconnector, and solid electrolyte layer is produced.
First, for example, NiO powder, Ni powder, and YSZ powder are mixed, a pore agent is added thereto, and an acrylic binder and toluene are mixed to prepare a paste for the active fuel electrode layer molded body 13a. Similarly, a paste for the interconnector 13d is produced using, for example, LaCrO ₃ oxide powder.

Next, for example, NiO powder, Ni powder, and rare earth element oxide such as Y ₂ O ₃ are mixed, a pore agent is added thereto, and an acrylic binder and toluene are mixed to form a slurry. The slurry is applied and dried to prepare a current collecting fuel electrode layer tape (green sheet) 13f having a predetermined dimension and a thickness of 80 to 200 μm.

  On the current collecting fuel electrode layer tape 13f, as shown in FIG. 4 (a), the active fuel electrode layer molded body 13a and the interconnector 13d paste are sequentially laminated and dried to obtain the active fuel electrode layer. Formed body 13a and interconnector 13d are formed.

  Next, as shown in FIG. 4 (b), in the collector fuel electrode layer tape 13f, a plurality of locations forming the insulating portion are punched out, and the active fuel electrode layer molded body 13a and the interconnector 13d are laminated. The electrofuel electrode layer tape 13f is prepared (see FIG. 4B).

  Thereafter, as shown in FIG. 4 (c), the active fuel electrode layer molded body 13a and the collector fuel electrode layer tape 13f on which the interconnector 13d is formed are used as the first reaction gas of the porous support body molded body 12. Attached to the surface of the porous support body 12 that has been calcined at a distance of 20 to 25 mm from the end on the discharge side and a spacing of 1.0 to 20 mm between adjacent sheets. This process is repeated, and a plurality of current collecting fuel electrode layer tapes 13f on which the active fuel electrode layer formed body 13a and the interconnector 13d are respectively printed and laminated are attached to the surface of the porous support formed body 12 in a horizontal stripe pattern.

  Next, the porous support body molded body 12 is dried in this state, and then calcined at a temperature range of 900 to 1300 ° C. for 2 to 4 hours. Next, as shown in FIG. 4D, a masking tape 16 is attached to the surface layer portion of the interconnector 13d.

Next, this laminated body is filled with the solid electrolyte layer molded body 13b and the solid electrolyte film molded body 14a.
If the solid electrolyte layer molded body 13b and the solid electrolyte film molded body 14a are made of the same material, the laminate is immersed in a solution for the solid electrolyte layer molded body 13b in which 8YSZ is added with an acrylic binder and toluene to form a slurry. Then, the solid electrolyte layer molded body 13b is taken out from the solution. As a result, as shown in FIG. 4E, the layer of the solid electrolyte layer molded body 13b is applied to the entire surface of the laminate, and the solid electrolyte layer molded body 13b is also formed in the space punched out in FIG. Filled. At this time, if necessary, the end of the porous support molded body 12 on the first reaction gas discharge side is immersed in the solution for the solid electrolyte layer molded body 13b, so that the gas flow inside the porous support molded body 12 is increased. The solid electrolyte layer molded body 13 b may be formed on the inner surface of the path 15. Further, in the case where chamfering is performed on the outer peripheral corner of the end surface of the porous support body molding 12 on the first reaction gas discharge side, the solid electrolyte layer molding 13b may be formed along the chamfering. Good. In this state, calcining is performed at 600 to 1000 ° C. for 2 to 4 hours.
Hereinafter, the solid electrolyte layer molded body 13b of 20 to 25 mm from the end on the first reaction gas discharge side of the porous support molded body 12 in such a case is referred to as a solid electrolyte film molded body 14a.

If the solid electrolyte layer molded body 13b and the solid electrolyte film molded body 14a are different materials, the laminate is immersed in a solution for the solid electrolyte layer molded body 13b which is a slurry obtained by adding an acrylic binder and toluene to 8YSZ. Then, the solid electrolyte layer molded body 13b is taken out from the solution. As a result, as shown in FIG. 4 (e), the layer of the solid electrolyte layer molded body 13b is applied to the entire surface of the porous support molded body 12 spaced 20 to 25 mm away from the end on the first reaction gas discharge side. At the same time, the solid electrolyte layer molded body 13b is filled in the space punched out in FIG. In this state, calcining is performed at 600 to 1000 ° C. for 2 to 4 hours.
A portion of the obtained laminate in which the solid electrolyte layer molded body 13b is not formed is dipped in a solution for the solid electrolyte layer film molded body 14a in which an acrylic binder and toluene are added to lanthanum gallate to form a slurry. It removes from the solution for molded objects 14a. At this time, if necessary, the end of the porous support molded body 12 on the first reaction gas discharge side is immersed in the solution for the solid electrolyte coating molded body 14a, so that the gas flow inside the porous support molded body 12 is increased. A solid electrolyte film molded body 14 a may be formed on the inner surface of the path 15. Further, when chamfering is performed on the outer peripheral corner of the end face of the porous support molded body 12 on the first reaction gas discharge side, the solid electrolyte coated molded body 14a may be formed along the chamfer. Good. Furthermore, in this state, calcining is performed at 600 to 1000 ° C. for 2 to 4 hours.

  When the calcination is finished, as shown in FIG. 4F, the masking tape 16 and the unnecessary solid electrolyte layer molded body 13b on the masking tape 16 are removed. Next, the current collecting fuel electrode layer tape 13f, the active fuel electrode layer molded body 13a, the interconnector 13d, and the solid electrolyte layer molded body 13b are laminated on the porous support molded body 12 at 1450 to 1500 ° C. And firing for 2 to 4 hours.

Subsequently, the solid electrolyte film molded body 14a portion of the laminate is immersed in a solution (slurry) for the glass film molded body 14b containing a glassy powder mainly containing SiO ₂ , a binder, a solvent, and the like. Thus, the glass film molded body 14b is produced on the solid electrolyte film molded body 14a. At this time, when the solid electrolyte film molded body 14a is formed on the inner surface of the gas flow path 15 inside the porous support body molded body 12, the solid electrolyte film molded body 14a portion on the first reaction gas discharge side is provided. The glass film molded body 14b may be formed on the solid electrolyte film molded body 14a formed on the inner surface of the gas flow path 15 by immersing the end portion in the solution for the glass film molded body 14b. Further, when chamfering is performed on the outer peripheral corner of the end surface of the porous support body molding 12 on the first reaction gas discharge side, the solid electrolyte layer molding body 14a formed along the chamfering is formed. The glass film formed body 14b may be formed along the chamfer. In addition, immersion time can be suitably set so that the glass film forming body 14b may become the target thickness.

Next, for example, a slurry obtained by mixing lanthanum cobaltite (LaCoO ₃ ) and a solvent is printed on the solid electrolyte layer molded body 13b facing the active fuel electrode layer molded body 13a, as shown in FIG. 4 (g). The air electrode layer molded body 13c having a thickness of 10 to 100 μm is formed. And the formed air electrode layer molded body 13c is baked by heat treatment at 950 to 1150 ° C. for 2 to 5 hours.

Next, a slurry in which lanthanum cobaltite (LaCoO ₃ ) and an organic binder are mixed is printed on a portion where the cell connection member 13e is to be formed, and is baked at 900 to 1150 ° C. for 2 to 5 hours, thereby obtaining the cell stack 1. (See FIG. 4 (h)).

  In addition, about the lamination | stacking method of each layer which comprises the fuel cell 3, you may use any lamination method of tape lamination | stacking, paste printing, dip coating, and spray spraying. Preferably, the drying process at the time of lamination is a short time, and it is preferable to laminate each layer by tape lamination from the viewpoint of shortening the process time.

  By the manufacturing method as described above, the cell stack 1 in which the inner electrode layer is a fuel electrode layer (current collecting fuel electrode layer and active fuel electrode layer) and the outer electrode layer is an air electrode layer can be easily manufactured.

(Horizontal stripe solid oxide fuel cell bundle)
By forming the bundle 20, all the arranged cell stacks 1 can be electrically connected in series using the inter-stack connection member 22, and a desired power generation amount can be obtained efficiently. In addition, what is necessary is just to adjust the number of the cell stack 1 suitably according to the desired electric power generation amount.
FIG. 5 shows an example of a bundle 20 in which comb-like inter-stack connection members 22 are arranged between the cell stacks 1 according to the present embodiment.
By forming the bundle 20, all the arranged cell stacks 1 can be electrically connected in series using the inter-stack connection member 22, and a desired power generation amount can be obtained efficiently.
In addition, what is necessary is just to adjust the number of the cell stack 1 suitably according to the desired electric power generation amount.

  In the bundle 20, each cell stack 1 is fixed to the gas manifold 21 with, for example, an insulating adhesive (for example, glass). The gas manifold 21 and the support 22 may be made of a material having heat resistance. For example, the gas manifold 21 and the support 22 can be made of a material such as a metal made of silicon, iron, titanium oxide, aluminum oxide, or a ceramic having heat resistance.

(Fuel cell)
The fuel cell of the present invention is configured by storing a plurality of bundles 20 as described above in a storage container. Thereby, a fuel cell with improved long-term reliability can be obtained.

  EXAMPLES Hereinafter, although an Example and a comparative example are given and this invention is demonstrated further in detail, this invention is not limited by a following example.

<Production of cell stack>
Example 1
First, a porous support molded body was produced. As the material of the porous support molded body, NiO and Y ₂ O ₃ powder are blended and mixed with MgO powder having an average particle diameter (D ₅₀ ) of 2.8 μm, and the thermal expansion coefficient thereof is that of the solid electrolyte layer. Adjustments were made to match. This mixed powder is mixed with a solvent composed of a pore agent, a cellulosic organic binder, and water, extruded, and formed into a hollow plate-like shape having a gas channel inside, and a flat porous support. A molded body was prepared (see FIG. 3), dried, and calcined at 1100 ° C. for 4 hours to obtain a porous support molded body having a longitudinal direction of 350 mm and a width direction of 50 mm.

  Next, C surface processing was applied to the corners of the outer periphery of the end surface on the first reactive gas discharge side so that the shape after chamfering was C surface shape. The C surface was processed so that the length from the end of the gas flow path to the corner after C surface processing was 700 μm.

Next, NiO powder and YSZ powder were mixed, a pore agent was added thereto, and an acrylic binder and toluene were mixed to prepare a paste for an active fuel electrode layer molded body. Similarly, a paste for an interconnector was prepared using LaCrO ₃ oxide powder.

Next, NiO powder and Y ₂ O ₃ rare earth element oxide are mixed, a pore agent is added thereto, acrylic binder and toluene are mixed to form a slurry, and the slurry is applied by a doctor blade method. And dried to produce a current collecting fuel electrode layer tape. On the current collecting fuel electrode layer tape, the active fuel electrode layer and interconnector pastes were sequentially printed using a predetermined mesh plate making and dried to form an active fuel electrode layer molded body and an interconnector ( (See FIG. 4 (a)).
The interconnector molded body and the active fuel electrode layer molded body were formed on a current collecting fuel electrode layer tape with a gap of 300 μm.
Subsequently, the current collecting fuel electrode layer tape was cut in accordance with the shape of the fuel cell, and the portion forming the insulating portion was punched (see FIG. 4B).

  Thereafter, the current collector fuel electrode layer tape on which the active fuel electrode layer molded body and the interconnector molded body are laminated is calcined on the porous support body molded body, and the first reaction gas discharge side of the porous support body molded body A plurality of pieces were pasted at intervals of 2 mm along the longitudinal direction in the form of horizontal stripes with an interval of 25 mm from the end of the substrate (see FIG. 4C).

  Next, the porous support molded body was dried in this state, and then calcined at 1200 ° C. for 2 hours. Next, the masking tape was affixed on the surface layer part of the exposed interconnector molded body (see FIG. 4D).

Next, this laminate was dipped in a solid electrolyte layer molded body solution obtained by adding an acrylic binder and toluene to 8YSZ, and then taken out from the solid electrolyte layer molded body solution.
By this dipping, a solid electrolyte layer molded body was formed on the entire surface, and a solid electrolyte layer molded body was also provided on the insulating portion between adjacent cells (see FIG. 4 (e)). At this time, the end portion on the first reaction gas discharge side of the porous support molded body is immersed in the solution for the solid electrolyte layer molded body, and on the inner surface of the gas flow path inside the porous support molded body, A solid electrolyte layer molded body was formed 20 mm from the end of the support molded body on the first reaction gas discharge side. Further, a solid electrolyte layer molded body was formed along the chamfer at the corner of the outer edge of the end surface of the porous support molded body.
Hereinafter, the solid electrolyte layer molded body of 20 mm from the end on the first reaction gas discharge side of the porous support molded body in such a case is referred to as a solid electrolyte film molded body.

  In this state, it was calcined at 900 ° C. for 2 hours. When the calcination was finished, the masking tape and the unnecessary solid electrolyte layer formed body on the masking tape were removed (see FIG. 4F). Next, a current collecting fuel electrode layer molded body, an active fuel electrode layer molded body, an interconnector molded body, and a solid electrolyte layer molded body are laminated on the porous support body molded body at 1480 ° C. for 2 hours. Was fired.

Subsequently, the solid electrolyte film molded body (one end portion of the non-power generation section) on the first reaction gas discharge side of the molded fuel cell body is a glass containing SiO ₂ as a main component and containing a binder and a solvent. Immerse in a solution for a film molded body, and form a glass film molded body on the solid electrolyte film molded body including the inside of the gas flow channel from the end of the first reaction gas discharge side of the porous support molded body to 10 mm. Then, a baking treatment was performed at 1050 ° C. for 2 hours to form a glass film.

Next, a slurry obtained by mixing lanthanum cobaltite (LaCoO ₃ ) and isopropyl alcohol is printed on a solid electrolyte layer molded body facing the active fuel electrode layer molded body to form an air electrode layer molded body. The polar layered product was baked at 1100 ° C. for 2 hours to form an air electrode layer having a thickness of 50 μm (see FIG. 4G).

Finally, a slurry obtained by mixing lanthanum cobaltite (LaCoO ₃ ) and isopropyl alcohol is printed on the solid electrolyte layer of the adjacent fuel cell from the air electrode layer, and baked at 1000 ° C. for 4 hours. A cell connection member was formed to obtain the cell stack of the example (see FIG. 4 (h)).

(Comparative Example 1)
A cell stack of Comparative Example 1 was obtained in the same manner as in the Example except that the glass film was not formed.

(Comparative Example 2)
A cell stack of Comparative Example 2 was obtained in the same manner as in the Example, except that the corner of the outer periphery of the end face of the porous support molded body on the first reaction gas discharge side was not processed and a glass film was not formed. .

(Comparative Example 3)
An area of 20 mm from the end on the first reaction gas discharge side of the porous support molded body without working the outer peripheral corners of the end face of the porous support molded body on the first reaction gas discharge side (implementation) A cell stack of Comparative Example 3 was obtained in the same manner as in Example except that the solid electrolyte coated molded body and the glass coating were not formed on the solid electrolyte coated molded body laminate portion in the cell stack of Example 1.

<Evaluation test>
About each cell stack obtained by the Example and the comparative example, the 900 degreeC heating / cooling cycle test was done, and each durability was investigated. The test method is as follows.

(900 ° C heating / cooling cycle test)
The cell stack is stored in the storage container, N ₂ and H ₂ are used as fuel gas (first reaction gas), N ₂ : 1.67 L / min, and H ₂ : 0.00 in the gas flow path of the cell stack, respectively. The flow rate was 42 L / min, and air (second reaction gas) was flowed to the outer surface of the cell stack at a flow rate of 48 L / min. And it heated from the outside of a storage container, and raised the temperature in a container from room temperature to 900 degreeC with the temperature increase rate of 500 degreeC / hour. When the temperature in the container reached 900 ° C., the supply of N ₂ was stopped with the air flow rate kept unchanged, the flow rate of H ₂ was increased to 0.644 L / min, and the flow rate was maintained for 30 minutes under these conditions. Thereafter, the temperature was lowered to room temperature (about 50 ° C.) at a temperature lowering rate of 500 ° C./hour under the same gas supply conditions as those for the temperature raising. The process of raising the temperature from 50 ° C. to 900 ° C. and lowering the temperature again to 50 ° C. was taken as one cycle. Then, the number of cycles in which the end of the cell stack 1 in the storage container on the discharge port 5b side was damaged was examined. The results are shown in Table 1.

  As shown in Table 1, the corners on the outer periphery of the end face of the porous support molded body on the first reactive gas discharge side are processed, and the end of the porous support molded body on the first reactive gas discharge side To 20 mm from the end of the first reactant gas discharge side of the solid electrolyte-coated molded body and the porous support molded body to the region of 20 mm from the solid electrolyte-coated molded body laminate in the cell stack of Example 1 In the cell stack of the example in which is formed, the cell stack of Comparative Example 1 that does not form a glass film, without processing the corners of the outer periphery of the end face of the porous support molded body on the first reaction gas discharge side, The cell stack of Comparative Example 2 in which no glass film is formed, and the first corner of the porous support molded body without processing the outer peripheral corners of the end surface of the porous support molded body on the first reaction gas discharge side Reaction gas discharge end Compared to the cell stack of Comparative Example 3 in which the solid electrolyte coated molded body and the glass coating are not formed in the region of 20 mm to 20 mm (solid electrolyte coated molded body laminated portion in the cell stack of Example 1) The number of times to destruction was greatly improved. Therefore, it can be confirmed that a solid electrolyte coating is provided on at least a part of the other end portion of the porous support, and the end fracture can be suppressed by providing a glass coating on the solid electrolyte coating. It was.

DESCRIPTION OF SYMBOLS 1 Horizontal stripe type solid oxide fuel cell stack 2 Porous support body 2a Chamfer part of porous support body 2b Non-power generation area 3 Fuel cell 3a Inner electrode layer 3b Solid electrolyte layer 3c Outer electrode layer 3d Interconnector 3e Cell connection Member 4 Reinforcing coating 4a Solid electrolyte coating 4b Glass coating 4c Chamfered portion of electrolyte coating 4d Chamfered portion of glass coating 5 Gas flow path 5a First reaction gas inlet 5b First reaction gas outlet 12 Porous support molded body 13a Inner electrode layer molded body 13b Solid electrolyte layer molded body 13c Outer electrode layer molded body 13d Cell connecting member molded body 13e Interconnector 13f Current collecting fuel electrode layer tape 15 Gas flow path 20 Horizontal stripe type solid oxide fuel cell bundle 21 Gas manifold 22 Stack connection member

Claims (6)

A gas flow path for flowing the first reaction gas along the longitudinal direction is provided inside, the first reaction gas introduction port of the gas flow path is provided on one end side, and the gas flow path is provided on the other end side. A fuel in which an inner electrode layer, a solid electrolyte layer, and an outer electrode layer are laminated in this order on a portion excluding at least the other end on an electrically insulating porous support having a first reactive gas discharge port. A plurality of battery cells are arranged along the longitudinal direction of the porous support, and the fuel cell is supplied to the inner electrode layer via the porous support. And a horizontal stripe solid oxide fuel cell stack that generates electric power with the second reaction gas supplied to the outer electrode layer,
A horizontally striped solid oxide fuel cell comprising a solid electrolyte coating provided on at least a part of the other end of the porous support, and a glass coating provided on the solid electrolyte coating. stack.   The inner electrode layer is a fuel electrode layer, the outer electrode layer is an air electrode layer, the first reaction gas is a fuel gas, and the second reaction gas is an oxygen-containing gas. 2. A horizontally-striped solid oxide fuel cell stack according to 1.   The said solid electrolyte membrane and the said glass membrane are provided in the outer peripheral surface of the said porous support body in the other end part of the said porous support body, an end surface, and the inner surface of the said gas flow path. Horizontally striped solid oxide fuel cell stack.   The horizontal stripe according to any one of claims 1 to 3, wherein the solid electrolyte coating and the glass coating are provided on a chamfered portion formed by chamfering an outer peripheral corner at the other end of the porous support. Type solid oxide fuel cell stack.   One end side of the horizontal stripe type solid oxide fuel cell stack according to any one of claims 1 to 4 is fixed to a gas manifold for supplying the reaction gas to the gas flow path. A horizontally-striped solid oxide fuel cell bundle characterized by:   A fuel cell comprising a plurality of horizontally-striped solid oxide fuel cell bundles according to claim 5 housed in a housing container.

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