Electrochemical device

Information

  • Patent Grant
  • 10938047
  • Patent Number
    10,938,047
  • Date Filed
    Monday, January 14, 2019
    5 years ago
  • Date Issued
    Tuesday, March 2, 2021
    3 years ago
Abstract
A fuel cell device includes an electrochemical cell, an oxidizer gas supply portion, and a contaminant trap portion. An oxidizer gas supply portion has an oxidizer gas supply port for supplying an oxidizer gas to the cathode. A contaminant trap portion is disposed on a portion of the cathode on the side with the oxidizer gas supply port and exhibits oxygen ion conductivity and electron conductivity.
Description
BACKGROUND
Technical Field

The present invention relates to an electrochemical device.


Description of the Related Art

Typically, a solid oxide fuel cell includes a solid electrolyte layer disposed between an anode and a cathode. During the operation of the solid oxide fuel cell, the anode is supplied with a fuel gas (for example, hydrogen gas), and the cathode is supplied with an oxidizer gas (for example, air).


Japanese Patent Application Laid-Open No. 2015-090788 discloses a method of placing a contaminant trap portion between an oxidizer gas supply port and the cathode in order to inhibit a reduction in the catalytic activity of the cathode resulting from a contaminant that is present in the oxidizer gas. The contaminant trap portion is separated from the cathode to avoid functioning as an electrical current pathway.


SUMMARY

However, the method disclosed in Japanese Patent Application Laid-Open No. 2015-090788 does not configure the contaminant trap portion in an active state since a current does not flow into the contaminant trap portion, and therefore there is a limitation on the effective trapping of contaminants.


The present invention is proposed in light of the circumstances described above, and has the purpose of providing an electrochemical device that enables the effective trapping of contaminants in an oxidizer gas.


An electrochemical device according to a first aspect of the present invention includes an electrochemical cell, an oxidizer gas supply portion, and a contaminant trap portion. The electrochemical cell has an anode, a cathode that exhibits an oxygen ion conductivity and an electron conductivity, and a solid electrolyte layer that is disposed between the anode and the cathode. The oxidizer gas supply portion has an oxidizer gas supply port for supplying an oxidizer gas to the cathode. The contaminant trap portion is disposed on a portion of the cathode on the side with the oxidizer gas supply port and exhibits an oxygen ion conductivity and an electron conductivity.


An electrochemical device according to a second aspect of the present invention includes an electrochemical cell, an oxidizer gas discharge portion, and a contaminant trap portion. The electrochemical cell has an anode, a cathode that exhibits an oxygen ion conductivity and an electron conductivity, and a solid electrolyte layer that is disposed between the anode and the cathode. The oxidizer gas discharge portion has an oxidizer gas discharge port for discharging an oxidizer gas that was supplied to the cathode. The contaminant trap portion is disposed on a portion of the cathode on the side with the oxidizer gas discharge port and exhibits an oxygen ion conductivity and an electron conductivity.


The present invention enables the provision of an electrochemical device that enables the effective trapping of contaminants in an oxidizer gas.





BRIEF DESCRIPTION OF THE DRAWINGS

Referring now to the attached drawings which form a part of this original disclosure:



FIG. 1 is a perspective view of a fuel cell stack according to a first embodiment.



FIG. 2 is a perspective view of a fuel cell according to a first embodiment.



FIG. 3 is a sectional view of a fuel cell according to a first embodiment.



FIG. 4 is a sectional view of a fuel cell device according to a second embodiment.



FIG. 5 is a sectional view of a fuel cell device according to modified example of a second embodiment.





DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Selected embodiments will now be explained with reference to the drawings. It will be apparent to those skilled in the art from this disclosure that the following descriptions of the embodiments are provided for illustration only and not for the purpose of limiting the invention as defined by the appended claims and their equivalents.


1. First Embodiment

Fuel Cell Stack 100



FIG. 1 is a perspective view of a fuel cell stack 100. The fuel cell stack 100 includes a plurality of fuel cells 1 and a manifold 2. In the present embodiment, the fuel cells 1 are an example of an electrochemical cell and the fuel cell stack 100 is an example of an electrochemical device.


The plurality of fuel cells 1 is arranged in series along an array direction. Each fuel cell 1 is disposed approximately in parallel in a substantially equidistant configuration. A base end 3 of each fuel cell 1 is fixed to the manifold 2. A distal end 4 of each fuel cell 1 is a free end. In this manner, each fuel cell 1 is supported in a cantilevered state by the manifold 2. The configuration of the fuel cell 1 will be described below.


The manifold 2 is configured to distribute gas to each fuel cell 1. The manifold 2 is hollow and has an internal cavity. The internal cavity of the manifold 2 is supplied with a fuel gas (for example, hydrogen) from a fuel gas supply source (not shown).


The manifold 2 supports each fuel cell 1. The manifold 2 includes a manifold main body 2a, a top plate 2b, and an inflow pipe 2c. In the present embodiment, the manifold main body 2a, the top plate 2b, and the inflow pipe 2c are mutually separate members but may be provided in an integrated configuration.


The manifold main body 2a has a substantially rectangular shape and includes an inner cavity with an open upper surface. The manifold main body 2a for example may be configured by a metal material that exhibits heat resistant properties (for example, ferritic stainless steel, austenitic stainless steel, and Ni-based alloy, or the like).


The top plate 2b is disposed on the manifold main body 2a to thereby close the upper surface of the manifold main body 2a. The top plate 2a for example is bonded to the manifold main body 2a, for example, by the use of crystalline glass. The top plate 2b may be configured by the same material as that used in the manifold main body 2a.


The top plate 2b has a plurality of through holes 2d. Each through hole 2d connects the inner cavity of the manifold 2 to an external cavity. The base end 3 of each fuel cell 1 is inserted into each through hole 2d. The base end 3 of each fuel cell 1 is fixed to a through hole 2d by a bonding agent (for example, crystalline glass or the like). Crystalline glass, for example, includes the use of SiO2—B2O3-based, SiO2—CaO-based, or SiO2—MgO-based configurations.


External Configuration of Fuel Cell 1


Next, the external configuration of the fuel cell 1 will be described. FIG. 2 is a perspective view of a fuel cell 1.


The fuel cell 1 is a segmented-in-series solid oxide fuel cell (SOFC: solid oxide fuel cell). The fuel cell 1 includes 8 power generating elements A, a support substrate 10, a seal layer 11 and a front-rear connecting member 12.


Four power generating elements A of the 8 power generating elements A are disposed at a predetermined interval on the front surface of the support substrate 10 along the longitudinal direction of the support substrate 10, and are electrically connected in series. The remaining 4 power generating elements A are disposed at a predetermined interval on the rear surface of the support substrate 10 along the longitudinal direction of the support substrate 10, and are electrically connected in series.


In the following description, the power generating element A that is closest to the manifold 2 of the 4 power generating elements A that are disposed on the front surface of the support substrate 10 is termed the “base-end-side power generating element Ak” and the power generating element A that is closest to the manifold 2 of the 4 power generating elements A disposed on the rear surface of the support substrate 10 is termed the “base-end-side power generating element Aj.” The base-end-side power generating element Ak and the base-end-side power generating element Aj are respectively power generating elements A that are disposed on the base end 3. The base-end-side power generating element Ak and the base-end-side power generating element Aj are respectively the closest power generating elements A to an inflow port of a gas flow passage 10a that is described below.


An outer surface of each power generating element A is supplied with an oxidizer gas. The oxidizer gas flows from the base end side towards the distal end side of the support substrate 10. The oxidizer gas, for example, includes the use of a mixed gas of oxygen and another gas. It is particularly preferred that the oxidizer gas is safe and cost-effective air. The oxidizer gas may contain an inert gas such as nitrogen, argon, or the like.


The support substrate 10 is a flat plate that extends in a longitudinal direction. The support substrate 10 is configured by a porous material that does not exhibit an electron conductivity. The support substrate 10 for example may be configured by CSZ (calcia-stabilized zirconia). The support substrate 10 supports the 8 power generating elements A.


A plurality of gas flow passages 10a is formed in an inner portion of the support substrate 10. Each gas flow passage 10a is formed in a substantially parallel configuration at approximately equal intervals in the lateral direction of the support substrate 10. Each gas flow passage 10a extends along the longitudinal direction of the support substrate 10. Each gas flow passage 10a opens at both longitudinal end faces of the support substrate 10. Each gas flow passage 10a includes a fuel gas inflow port that is formed on the end face of the base end side of the support substrate 10 and a fuel gas outflow port that is formed on the end face of the distal end side of the support substrate 10.


The fuel gas includes hydrogen, a hydrocarbon, and a mixed gas of hydrogen and a hydrocarbon. The hydrocarbon includes, for example, natural gas, naphtha, and coal gasification gas, or the like. However, there is no limitation in this regard. The fuel gas may be a single type of hydrocarbon, or may be a mixture of two or more hydrocarbons. The fuel gas may contain an inert gas such as nitrogen, argon, or the like.


The seal layer 11 covers an external surface of the support substrate 10. The seal layer 11 may be configured by a dense material. The dense material, for example, includes YSZ, ScSZ, glass, spinel oxides, or the like. The seal layer 11 may be integrated by the use of a material that is the same as the solid electrolyte layer 40 of each of the power generating element A as described below.


The front-rear connecting member 12 is placed to encompass the distal end 4. The front-rear connecting member 12 enables an electrical connection in series of 2 front and back power generating elements A that are disposed on the distal end 4.


The front-rear connecting member 12, for example, may be configured by LSCF=(La, Sr)(Co, Fe)O3 (lanthanum strontium cobalt ferrite), LSC=(La, Sr)CoO3 (lanthanum strontium cobaltite), or La(Ni, Fe, Cu)O3, or the like.


Inner Configuration of Fuel Cell 1


Next, the inner configuration of the fuel cell 1 will be described. FIG. 3 is a sectional view of a P surface of the fuel cell 1.


Each power generating element A of the fuel cell 1 includes an anode 20, an interconnector 30, the solid electrolyte layer 40, a barrier layer 50, a cathode active portion 60, and a cathode current collecting portion 70.


The anode 20 includes an anode current collecting portion 21 and an anode active portion 22. The anode current collecting portion 21 is disposed on the support substrate 10. The anode current collecting portion 21 for example may be configured by NiO (nickel oxide) and YSZ (8YSZ) (yttria-stabilized zirconia). Although there is no particular limitation on the thickness of the anode current collecting portion 21, it may be configured, for example, as 50 to 500 μm. The anode active portion 22 is disposed on the anode current collecting portion 21. The anode active portion 22 for example may be configured by NiO (nickel oxide) and YSZ (8YSZ) (yttria-stabilized zirconia). Although there is no particular limitation on the thickness of the anode active portion 22, it may be configured for example as 5 to 30 μm.


The interconnector 30 is disposed in a separate position from the anode active portion 22 on the anode current collecting portion 21. The interconnector 30 is configured from a dense material that exhibits an electron conductivity. The interconnector 30 for example is configured using LaCrO3 (lanthanum chromite). Although there is no particular limitation on the thickness of the interconnector 30, for example, it may be configured as 10 to 100 μm.


The solid electrolyte layer 40 is disposed to cover the anode 20. The solid electrolyte layer 40 is placed in contact with the respective interconnectors 30 of adjacent power generating elements A. The solid electrolyte layer 40 is configured from a dense material that exhibits an ion conductivity and does not exhibit an electron conductivity. The solid electrolyte layer 40 is configured, for example, by YSZ (8YSZ) (yttria-stabilized zirconia). Although there is no particular limitation on the thickness of the solid electrolyte layer 40, for example, it may be configured as 3 to 50 μm.


The barrier layer 50 is disposed to cover the solid electrolyte layer 40. The barrier layer 50 is configured from a dense material. The barrier layer 50 is configured, for example, by GDC ((Ce, Gd)O2: gadolinium-doped ceria). Although there is no particular limitation on the thickness of the solid electrolyte layer 40, for example, it may be configured as 3 to 50 μm.


The cathode active portion 60 is disposed to cover the barrier layer 50. The cathode active portion 60 is the portion that is responsible for power generation reactions in the fuel cell 1. The cathode active portion 60 exhibits an oxygen ion conductivity and an electron conductivity. The cathode active portion 60 contains a main component which is a composite material that is a mixture of an oxygen ion conductive material and an electron conductive material, or a mixed conductive material exhibiting both oxygen ion and electron conductivity.


In the present embodiment, the term composition X “contains as a main component” material Y means that material Y preferably occupies at least 60 wt % of the total of composition X, more preferably occupies at least 70 wt %, and still more preferably occupies at least 90 wt %.


The mixed conductive material includes a perovskite composite oxide that contains at least one of Sr and La at the A site and that is expressed by the general formula ABO3. This type of perovskite composite oxide includes a material such as LSF, that is to say, (La, Sr) FeO3, and LSC, that is to say, (La, Sr)CoO3, or the like, and in particular, LSCF, that is to say, (LaSr)(CoFe)O3 is preferred. The cathode active portion 60 may contain a zirconia-based material such as yttria-stabilized zirconia including 3YSZ, 8YSZ, 10YSZ or the like, scandia-stabilized zirconia such as ScSZ, or the like.


Although there is no particular limitation on the thickness of the cathode active portion 60, for example, it may be configured to be from 5 to 100 μm.


The cathode current collecting portion 70 is disposed on the cathode active portion 60. The cathode current collecting portion 70 is placed in contact with the cathode active portions 60 and the interconnectors 30 of adjacent power generating elements A. The cathode current collecting portion 70 is a porous fired body. The cathode current collecting portion 70 is the portion that supplies electrons required for power generation reactions in the fuel cell 1 to the cathode active portion 60.


The cathode current collecting portion 70 exhibits a higher electron conductivity than the cathode active portion 60. The cathode current collecting portion 70 may omit oxygen ion conductivity properties, or may exhibit an oxygen ion conductivity. Although the material used in the cathode current collecting portion 70 includes the use of a metal material such as Ag (silver), Ag—Pd (silver palladium alloy), or the like, a material including a main component being a perovskite composite oxide that contains at least one of Sr and La at the A site and that is expressed by the general formula ABO3 is suitable. A material including a main component of a perovskite composite oxide that contains at least one of Sr and La at the A site and that is expressed by the general formula ABO3, for example, includes (La, Sr)CoO3, La(Ni, Fe, Cu)O3, or the like. In particular, a perovskite composite oxide is preferred as expressed by Formula (1) below.

La(Ni1-x-yFexCuy)O3-δ  (1)


It is noted that in Formula (1), x is greater than or equal to 0.03 and less than or equal to 0.3, y is greater than or equal to 0.05 and less than or equal to 0.5, and 8 is greater than or equal to 0 and less than or equal to 0.8. However, it is noted that the arrangement of Ni1-x-yFexCuy at the B site is not affected by the x value and y value.


Although there is no particular limitation on the thickness of the cathode current collecting portion 70, for example, it may be configured to be from 30 to 500 μm.


In this context, the respective base-end-side power generating element Ak and the base-end-side power generating element Aj include the further provision of a contaminant trap portion 80.


The contaminant trap portion 80 is disposed on the cathode current collecting portion 70. The contaminant trap portion 80 traps (adsorbs, removes) a contaminant contained in the oxidizer gas that flows along a surface and/or an inner portion.


Here, a “contaminant” is defined as a substance in the oxidizer gas that can be adsorbed by the cathode 60 to decrease catalytic activity. For example, when a contaminant reacts with the compound oxide in the cathode 60 and generates a reaction product, this reaction product blocks the holes in the cathode 60 and the cathode 60 is no longer supplied with a sufficient amount of oxidizer gas. As a result, there is insufficient catalytic activity of the cathode 60. There is also the possibility that the contaminant will react with the compound oxide of the cathode 60 and be transformed into another substance that has no catalytic activity. When the catalytic activity of the cathode 60 decreases, the fuel cell 1 loses power generation performance.


Examples of the contaminant include a substance (for example, SOx) containing at least one type of element among S, Cr, Si, B and Cl. The contaminant may contain H2O.


The contaminant trap portion 80 exhibits an oxygen ion conductivity and an electron conductivity. The contaminant trap portion 80 contains a main component which is a composite material that is a mixture of an oxygen ion conductive material and an electron conductive material, or a mixed conductive material exhibiting both an oxygen ion conductivity and an electron conductivity. The mixed conductive material may be the material given above as examples of a material for use in the cathode active portion 60. The contaminant trap portion 80 may include the constituent material for the cathode active portion 60, or may omit the constituent material for the cathode active portion 60.


It is more preferred that the contaminant trap portion 80 includes a contaminant as described above. In this manner, the efficient trapping of contaminants is enabled due to the enhanced reactivity of the contaminant trap portion 80. Inclusion of a contaminant in the contaminant trap portion 80 may be performed by doping a material that exhibits an oxygen ion conductivity and an electron conductivity as described above with a contaminant and then applying a thermal treatment (600 degrees C. to 11200 degrees C., 1 hour to 120 hours).


The contaminant trap portion 80 enables the permeation of the oxidizer gas. Although there is no particular limitation in relation to the porosity of the contaminant trap portion 80, it may be configured to have a porosity of greater than or equal to 10% and less than or equal to 50% as measured by an Archimedes Method. Although there is no particular limitation in relation to the shape of the contaminant trap portion 80, for example, it may be rectangular, spherical or the like in addition to membranous, layered or a plate shape.


In this manner, the contaminant trap portion 80 that exhibits an oxygen ion conductivity and an electron conductivity is disposed on the cathode current collecting portion 70 at the respective base-end-side power generating element Ak and the base-end-side power generating element Aj that are closest to the manifold 2. Therefore, the activity of the contaminant trap portion 80 itself can be enhanced to thereby enable the contaminant trap portion 80, together with the cathode current collecting portion 70, to function as a portion of the electrical current pathway associated with chemical reactions in the fuel cell 1. Consequently, contaminants can be efficiently trapped by the contaminant trap portion 80. Furthermore, since the contaminant trap portion 80 is respectively placed in the base-end-side power generating element Ak and the base-end-side power generating element Aj that are closest to the manifold 2, supply of the oxidizer gas to each power generating element A is enabled after the trapping (adsorption, removal) of contaminants.


Method of Manufacturing Fuel Cell 1


Next, an example of a method of manufacturing the fuel cell 1 will be described.


Firstly, a support substrate material as described above is extrusion molded to form a green body for the support substrate 10 that includes the gas flow passage 10a. Then a recessed portion is formed on the front and rear surfaces of the green body for the support substrate 10 to thereby accommodate a green body for the anode current collecting portion 21.


Then, an anode current collecting portion material as described above is configured as a paste and screen printed to thereby form a green body for the anode current collecting portion 21 in the recessed portion of the support substrate 10. In addition, a recessed portion is formed on the front surface of the green body for the anode current collecting portion 21 to thereby accommodate a green body for the anode active portion 22 and the interconnector 30.


Then, an anode active portion material as described above is configured as a paste and screen printed to thereby form a green body for the anode active portion 22 in the recessed portion of the anode current collecting portion 21.


Then, an interconnector material as described above is configured as a paste and screen printed to thereby form a green body for the interconnector 30 in the recessed portion of the anode current collecting portion 21.


Then, a solid electrolyte layer material as described above is configured as a paste and screen printed to thereby form a green body for the solid electrolyte layer 40 on the green body for the interconnector 30 and the anode 20.


Then, a barrier layer material is dip molded onto the green body for the solid electrolyte layer 40 to thereby form a green body for the barrier layer 50.


Next, the respective green bodies for the support substrate 10, the anode 20, the interconnector 30, the solid electrolyte layer 40 and the barrier layer 50 are co-fired (1300 to 1600 degrees C., 2 to 20 hours).


Then, a cathode active portion material as described above is configured as a paste and screen printed onto the barrier layer 50 to thereby form a green body for the cathode active portion 60.


Then, a cathode current collecting portion material as described above is configured as a paste and screen printed onto the green body for the cathode active portion 60 to thereby form a green body for the cathode current collecting portion 70.


Then, a contaminant trap portion material as described above is configured as a paste and screen printed onto the green body for the cathode current collecting portion 70 to thereby form a green body for the contaminant trap portion 80.


Next, the respective green bodies for the cathode active portion 60, the cathode current collecting portion 70 and the contaminant trap portion 80 are fired (900 to 1100 degrees C., 1 to 20 hours).


2. Second Embodiment

Configuration of Fuel Cell Device 101


The configuration of the fuel cell device 101 according to a second embodiment will be described making reference to the drawings. FIG. 4 is a sectional view of a fuel cell device 101.


The fuel cell device 101 includes a fuel cell 110, an interconnector 120, a separator 130, an oxidizer gas supply portion 140, an oxidizer gas discharge portion 150 and a contaminant trap portion 170. A fuel cell stack is configured by stacking a plurality of layers of the fuel cell device 101. In the present embodiment, the fuel cell 110 is an example of an electrochemical cell and the fuel cell device 101 is an example of an electrochemical device.


Fuel Cell 110


The fuel cell 110 includes a solid electrolyte layer 111, an anode 112, a cathode 113, an anode-side current collecting portion 114, and a cathode-side current collecting portion 115.


The fuel cell 110 according to the present embodiment is an anode-supported cell having a conspicuously thick anode 112 in comparison to the cathode 113 and the solid electrolyte layer 111. However, there is no limitation in this regard. The fuel cell 110 may be a cathode-supported cell having a conspicuously thick cathode 113 in comparison to the anode 112 and the solid electrolyte layer 111, or may be a solid electrolyte layer-supported cell having a conspicuously thick solid electrolyte layer 111 in comparison to the anode 112 and the cathode 113.


The solid electrolyte layer 111 is formed as a thin plate. The thickness of the solid electrolyte layer 111 may be configured to be greater than or equal to 3 μm and less than or equal to 20 μm. The solid electrolyte layer 111 is configured by an electrolytic material that exhibits an oxygen ion conductivity in which oxygen ions produced at the cathode 113 migrate to the anode 112. This type of electrolytic material, for example, includes the use of one type, or a combination of two or more types of yttria-stabilized zirconia (YSZ), scandia-stabilized zirconia (ScSZ), samarium added ceria (CeSmO2), gadolium added ceria (CeGdO2), and calcia-stabilized zirconia (CaSZ).


The solid electrolyte layer 111 is a dense substance. The solid electrolyte layer 111 prevents the permeation of an oxidizer gas toward the anode 112 and the permeation of fuel gas towards the cathode 113. The relative density of the solid electrolyte layer 111 obtained by the use of an Archimedes Method is preferably greater than or equal to 95%.


The anode 112 is disposed on a first main surface 1115 of the solid electrolyte layer 111. The anode 112 functions as an anode for the fuel cell 110. The anode 112 is a porous body.


The anode 112 is disposed in a fuel gas chamber S1. The fuel gas chamber S1 is supplied with a fuel gas from a fuel gas supply portion (not illustrated). The fuel gas includes hydrogen, a hydrocarbon, and a mixed gas of hydrogen and a hydrocarbon. The hydrocarbon includes, for example, natural gas, naphtha, and coal gasification gas, or the like. However, there is no limitation in this regard. The fuel gas may be a single type of hydrocarbon, or may be a mixture of two or more hydrocarbons. The fuel gas may contain an inert gas such as nitrogen, argon, or the like.


The anode 112 is configured by a known anode material. For example, the anode 112 may be configured using a mixture of the electrolytic material described above and a metal such as Ni and/or Fe, or the like.


The cathode 113 is disposed on a second main surface 111T of the solid electrolyte layer 111. The cathode 113 functions as a cathode for the fuel cell 110. The cathode 113 is a porous body. Although there is no limitation in relation to the porosity of the cathode 113, it may be configured to be greater than or equal to 110%. Although there is no limitation in relation to the thickness of the cathode 113, for example, it may be configured to be greater than or equal to 130 μm and less than or equal to 1200 μm.


The cathode 113 is disposed in an oxidizer gas chamber S2. The oxidizer gas chamber S2 is supplied with an oxidizer gas from an oxidizer gas supply portion 140. The oxidizer gas passes through the cathode 113 and then is discharged from the oxidizer gas chamber S2 by the oxidizer gas discharge portion 150. The oxidizer gas is preferably air.


The cathode 113 is configured using a material that exhibits an oxygen ion conductivity and an electron conductivity. This type of material is suitably a composite oxide that includes at least one type of element of La, Sr, Co and Fe. The composite oxide includes an La1-xSrxCoO3 composite oxide, an La1-xSrxFeO3 composite oxide, an La1-xSrxCo1-yFeyO3 composite oxide, an La1-xSrxMnO3 composite oxide, a Pr1-xBaxCoO3 composite oxide, and a Sm1-xSrxCoO3 composite oxide, or the like.


The anode-side current collecting portion 114 is electrically and mechanically connected with the anode 112. The constituent material used in the anode-side current collecting portion 114, for example, includes an Ni felt that exhibits a breathability. The anode-side current collecting portion 114 is sandwiched between the anode 112 and the interconnector 120 when the fuel cell device 101 is configured from a plurality of layers. It is noted that the anode-side current collecting portion 114 may be integrally formed with the interconnector 120.


The cathode-side current collecting portion 115 is electrically and mechanically connected with the cathode 113. The constituent material used in the cathode-side current collecting portion 115 includes, for example, a metal material such as Ag—Pd, or the like. The cathode-side current collecting portion 115 is sandwiched between the cathode 113 and the interconnector 120. It is noted that the cathode-side current collecting portion 115 may be integrally formed with the interconnector 120.


Interconnector 120


The interconnector 120 is electrically connected with the cathode 113. In the present embodiment, the interconnector 120 makes electrical contact with the cathode 113 through the cathode-side current collecting portion 115. The interconnector 120 is electrically and mechanically connected with the cathode-side current collecting portion 115. The interconnector 120 is sandwiched between two adjacent fuel cells 110 when the fuel cell device 101 is configured from a plurality of layers. In this case, the interconnector 120 is respectively electrically and mechanically connected with the anode-side current collecting portion 114 and the cathode-side current collecting portion 115.


The interconnector 120 may be configured by the use of a metal and is preferably configured by stainless steel.


Separator 130


The separator 130 is disposed to encircle the periphery of the fuel cell 110. The separator 130 according to the present embodiment is connected to the second main surface 111T of the solid electrolyte layer 111, and is disposed to encircle the cathode 113.


The separator 130 partitions the fuel gas chamber S1 and the oxidizer gas chamber S2. That is to say, in the same manner as the solid electrolyte layer 111, the separator 130 prevents the permeation of an oxidizer gas towards the anode 112 and the permeation of a fuel gas towards the cathode 113.


The separator 130 is configured by the use of a metal and is preferably configured by stainless steel.


Oxidizer Gas Supply Portion 140


The oxidizer gas supply portion 140 is disposed on the side of the fuel cell 110. The oxidizer gas supply portion 140 includes an oxidizer gas supply passage 141 and an oxidizer gas supply port 142.


The oxidizer gas supply passage 141 extends along a stacking direction of the fuel cell 110. When the fuel cell device 101 is configured from a plurality of layers, one oxidizer gas supply passage is formed by connecting the oxidizer gas supply passages 141.


The oxidizer gas supply port 142 is connected to the oxidizer gas supply passage 141. The oxidizer gas supply port 142 opens onto the oxidizer gas chamber S2. The oxidizer gas supply port 142 opens towards the fuel cell 110.


An oxidizer gas flows sequentially through the oxidizer gas supply passage 141 and the oxidizer gas supply port 142 and is thereby supplied to the oxidizer gas chamber S2. The oxidizer gas that is supplied from the oxidizer gas supply portion 140 to the oxidizer gas chamber S2, as shown in FIG. 1, flows along the flow direction D1 into the oxidizer gas chamber S2. The flow direction D1 is a direction from the oxidizer gas supply port 142 to the oxidizer gas discharge port 152 described below. The flow direction D1 is defined by a straight line that connects the center of the oxidizer gas supply port 142 and the center of the oxidizer gas discharge port 152. When there is the provision of a plurality of at least one of the oxidizer gas supply port 142 and the oxidizer gas discharge port 152, the flow direction D1 is defined by a straight line that connects the center of any one of the oxidizer gas supply ports 142 and the center of any one of the oxidizer gas discharge ports 152.


Oxidizer Gas Discharge Portion 150


The oxidizer gas discharge portion 150 is disposed on the side of the fuel cell 110. The oxidizer gas discharge portion 150 includes an oxidizer gas discharge passage 151 and an oxidizer gas discharge port 152.


The oxidizer gas discharge passage 151 extends along a stacking direction of the fuel cell 110. When the fuel cell device 101 is configured from a plurality of layers, one oxidizer gas discharge passage is formed by connecting the oxidizer gas discharge passages 151.


The oxidizer gas discharge port 152 is connected to the oxidizer gas discharge passage 151. The oxidizer gas discharge port 152 opens into the oxidizer gas chamber S2. The oxidizer gas discharge port 152 opens towards the fuel cell 110.


The oxidizer gas that is supplied from the oxidizer gas supply port 142 to the oxidizer gas chamber S2 and that has passed along the flow direction D1 into the oxidizer gas chamber S2 is discharged from the oxidizer gas discharge portion 152 into the oxidizer gas discharge passage 151.


Contaminant Trap Portion 170


The contaminant trap portion 170 in the present embodiment is disposed on a portion of the cathode 113 on the side with the oxidizer gas supply port 142. The portion of the cathode 113 on the side with the oxidizer gas supply port 142 is a portion in proximity to the oxidizer gas supply port 142 making reference to the center of the cathode 113 in the flow direction D1. The contaminant trap portion 170 is preferably disposed in proximity to the oxidizer gas supply port 142 and, as shown in FIG. 4, is more preferably disposed on an end portion of the cathode 113 on the side with the oxidizer gas supply port 142.


A contaminant is defined as a substance in the oxidizer gas that can be adsorbed by the cathode 113 to decrease the catalytic activity. For example, when a contaminant reacts with the compound oxide in the cathode 113 and generates a reaction product, this reaction products blocks the holes in the cathode 113 and the cathode 113 is no longer supplied with a sufficient amount of oxidizer gas. As a result, there is insufficient catalytic activity of the cathode 113. There is also the possibility that the contaminant will react with the compound oxide of the cathode 113 and be transformed into another substance that has no catalytic activity. When the catalytic activity of the cathode 113 decreases, the fuel cell 110 loses power generation performance.


Examples of the contaminant include a substance (for example, SOx) containing at least one type of element from among S, Cr, Si, B and Cl. The contaminant may contain H2O.


The contaminant trap portion 170 exhibits an oxygen ion conductivity and an electron conductivity. The contaminant trap portion 170 contains a main component which is a composite material that is a mixture of an oxygen ion conductive material and an electron conductive material, or a mixed conductive material exhibiting both an oxygen ion conductivity and an electron conductivity.


The contaminant trap portion 170 preferably contains a metal oxide. The metal oxide is preferably an oxide of at least one element selected from the group consisting of La, Sr, Sm, Gd, Pr, Nd, Co and Fe. The metal oxide is preferably a compound oxide.


It is preferred that the contaminant trap portion 170 further includes a contaminant as described above. In this manner, the efficient trapping of contaminants is enabled due to the enhanced reactivity of the contaminant trap portion 170. Inclusion of a contaminant in the contaminant trap portion 170 may be performed by doping a metal oxide as described above with a contaminant and then applying a thermal treatment (600 degrees C. to 11200 degrees C., 1 hour to 120 hours).


The contaminant trap portion 170 enables the permeation of the oxidizer gas. Although there is no particular limitation in relation to the porosity of the contaminant trap portion 170, it may be configured as a porosity of greater than or equal to 10% and less than or equal to 50% as measured by an Archimedes Method. Although there is no particular limitation in relation to the shape of the contaminant trap portion 170, for example, it may be rectangular, spherical or the like in addition to membranous, layered or a plate shape.


In this manner, the contaminant trap portion 170 that exhibits an oxygen ion conductivity and an electron conductivity is disposed on a portion of the cathode 113 on the side with the oxidizer gas supply port 142.


Therefore, the contaminant trap portion 170 together with the cathode 113 functions as a portion of the current pathway associated with chemical reactions in the fuel cell 110 and, thereby, the activity of the contaminant trap portion 170 itself is enhanced. Consequently, the efficient trapping of contaminants by the contaminant trap portion 170 is enabled.


Since the contaminant trap portion 170 is disposed on a portion on the side with the oxidizer gas supply port 142, it is possible to supply the oxidizer gas to the contaminant trap portion 170 prior to an increase in the temperature of the oxidizer gas to the atmospheric temperature in the oxidizer gas chamber S2. Therefore, since the oxidizer gas is supplied to the contaminant trap portion 170 at a relatively low temperature, there is a mild molecular motion in the contaminant trap portion 170. As a result, the efficient trapping of contaminants by the contaminant trap portion 170 is enabled.


Method of Manufacturing Fuel Cell Device 101


Next, an example of a method of manufacturing the fuel cell device 101 will be described.


Firstly, a slurry for the cathode 113 and a slurry for the contaminant trap portion 170 are coated and dried in sequence on the second main surface 111T of a green sheet for the solid electrolyte layer 111 that is stacked onto a green sheet for the anode 112 and fired to thereby form a fuel cell 110 and a contaminant trap portion 170.


Then a separator 130 is attached by brazing onto the second main surface 111T of the solid electrolyte layer 111.


The anode-side current collecting portion 114 is connected with the anode 112 and the cathode-side current collecting portion 115 and the interconnector 120 are sequentially connected with the cathode 113.


Then, an oxidizer gas supply portion 140 and an oxidizer gas discharge portion 150 are disposed on the side of the fuel cell 110 that is connected with the interconnector 120 and the separator 130.


3. Modified Example of Second Embodiment

The configuration of the fuel cell device 102 according to a modified example of the second embodiment will be described making reference to the drawings. FIG. 5 is a sectional view of the configuration of the fuel cell device 102.


The point of difference between the second embodiment described above and the modified example is the position of disposition of the contaminant trap portion. Therefore, the following description will focus on the point of difference.


The fuel cell device 101 includes a contaminant trap portion 170. The contaminant trap portion 170 is disposed on a portion of the cathode 113 on the side with the oxidizer gas discharge port 152. The portion of the cathode 113 on the side with the oxidizer gas discharge port 152 is a portion in proximity to the oxidizer gas discharge port 152 making reference to the center of the cathode 113 in the flow direction D1. The contaminant trap portion 170 is preferably disposed in proximity to the oxidizer gas discharge port 152 and, as shown in FIG. 5, is more preferably disposed on an end portion of the cathode 113 on the side with the oxidizer gas discharge port 152.


The contaminant trap portion 170 exhibits an oxygen ion conductivity and an electron conductivity. The contaminant trap portion 170 contains a main component which is a composite material that is a mixture of an oxygen ion conductive material and an electron conductive material, or a mixed conductive material exhibiting both an oxygen ion conductivity and an electron conductivity.


The contaminant trap portion 170 preferably contains a metal oxide. The metal oxide is preferably an oxide of at least one element selected from the group consisting of La, Sr, Sm, Gd, Pr, Nd, Co and Fe. The metal oxide is preferably a compound oxide.


It is preferred that the contaminant trap portion 170 further includes a contaminant (for example, at least one type of element of S, Cr, Si, B and Cl). In this manner, the efficient trapping of contaminants is enabled due to the enhanced reactivity of the contaminant trap portion 170. Inclusion of a contaminant in the contaminant trap portion 170 may be performed by doping a metal oxide as described above with a contaminant and then applying a thermal treatment (600 degrees C. to 11200 degrees C., 1 hour to 120 hours).


The contaminant trap portion 170 enables the permeation of the oxidizer gas. Although there is no particular limitation in relation to the porosity of the contaminant trap portion 170, it may be configured to have a porosity of greater than or equal to 10% and less than or equal to 50% as measured by an Archimedes Method. Although there is no particular limitation in relation to the shape of the contaminant trap portion 170, for example, it may be rectangular, spherical or the like in addition to membranous, layered or a plate shape.


In this manner, the contaminant trap portion 170 that exhibits an oxygen ion conductivity and an electron conductivity is disposed on a portion of the cathode 113 on the side with the oxidizer gas discharge port 152.


Therefore the contaminant trap portion 170, together with the cathode 113, functions as a portion of the current pathway associated with chemical reactions in the fuel cell 110 and, thereby, the activity of the contaminant trap portion 170 itself is enhanced. Consequently, the efficient trapping of contaminants by the contaminant trap portion 170 is enabled.


Since the contaminant trap portion 170 is disposed on a portion on the side with the oxidizer gas discharge port 152, when the operation of the fuel cell device 101 is stopped, a contaminant in the oxidizer gas is trapped as a result of backflow from the oxidizer gas discharge port 152 into the oxidizer gas chamber S2 that has a negative pressure as a result of a reduction in temperature.


Other Embodiments

Although an embodiment of the present invention has been described, the present invention is not limited to the above embodiment, and various modifications are possible within a scope that does not depart from the spirit of the invention.


Although the first embodiment described a fuel cell device 1 provided with a fuel cell 10 as an example of an electrochemical device provided with an electrochemical cell, and the second embodiment described a fuel cell device 100 as an example of an electrochemical device provided with an electrochemical cell, there is no limitation in this regard. The electrochemical device includes a configuration in which an electrochemical cell is an electrolytic cell that produces hydrogen and oxygen from water vapor.


Although the first embodiment described a segmented-in-series fuel cell 1 as an example of an electrochemical cell and the second embodiment described a flat plate fuel cell 1 as an example of an electrochemical cell, there is no limitation in this regard. The contaminant trap portion 80 according to the present invention may also be applied to an anode supported flat-tubular fuel cell.


In the first embodiment, the base-end-side power generating element Ak and the base-end-side power generating element Aj that are closest to the manifold 2 respectively include the contaminant trap portion 80. However, there is no limitation in this regard. A power generating element A other than the base-end-side power generating element Ak and the base-end-side power generating element Aj may include the contaminant trap portion 80, or at least one of the base-end-side power generating element Ak and the base-end-side power generating element Aj may include the contaminant trap portion 80. The contaminant trap portion 80 is preferably placed on a power generating element A that is upstream in relation to the gas flow direction of the oxidizer gas. Furthermore, the contaminant trap portion 80 is preferably placed in a region of the surface of the cathode-side current collecting portion 70 that is upstream in relation to the gas flow direction of the oxidizer gas.


REFERENCE SIGNS LIST






    • 1 FUEL BATTERY


    • 2 MANIFOLD


    • 100 FUEL CELL STACK

    • A POWER GENERATING ELEMENT

    • Ak BASE-END-SIDE POWER GENERATING ELEMENT

    • Aj BASE-END-SIDE POWER GENERATING ELEMENT




Claims
  • 1. An electrochemical device comprising: an electrochemical cell having an anode, a cathode exhibiting oxygen ion conductivity and electron conductivity, and a solid electrolyte layer disposed between the anode and the cathode;an oxidizer gas supply portion having an oxidizer gas supply port for supplying an oxidizer gas to the cathode; anda contaminant trap portion disposed on a portion of the cathode on the side with the oxidizer gas supply port and exhibiting oxygen ion conductivity and electron conductivity.
  • 2. An electrochemical device comprising: an electrochemical cell having an anode, a cathode exhibiting oxygen ion conductivity and electron conductivity, and a solid electrolyte layer that is disposed between the anode and the cathode;an oxidizer gas discharge portion having an oxidizer gas discharge port for discharging an oxidizer gas that was supplied to the cathode; anda contaminant trap portion disposed on a portion of the cathode on the side with the oxidizer gas discharge port and exhibiting oxygen ion conductivity and electron conductivity.
Priority Claims (1)
Number Date Country Kind
2018-196730 Oct 2018 JP national
US Referenced Citations (3)
Number Name Date Kind
20110053046 Gil et al. Mar 2011 A1
20130011767 Gil et al. Jan 2013 A1
20170141426 Ohmori May 2017 A1
Foreign Referenced Citations (4)
Number Date Country
2013-020982 Jan 2013 JP
2013-054970 Mar 2013 JP
2015-090788 May 2015 JP
2015-164094 Sep 2015 JP
Non-Patent Literature Citations (2)
Entry
U.S. Appl. No. 16/246,831, filed Jan. 14, 2019.
Office Action issued by the United States Patent and Trademark Office for corresponding U.S. Appl. No. 16/246,831, dated Jul. 13, 2020 (16 pages).
Related Publications (1)
Number Date Country
20200127313 A1 Apr 2020 US