JP2015069744A - Solid oxide fuel cell, solid oxide fuel cell stack, and spacer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent gas leakage.SOLUTION: A solid oxide fuel cell comprises: a single cell 1; a cell housing member 2 which houses the single cell 1; a fuel electrode side separator 3 which is laminated on the fuel electrode 11 side of the cell housing member 2 and supplies a fuel gas to a fuel electrode 11; an air electrode side separator 4 which is laminated on the air electrode 13 side of the cell housing member 2 and supplies an oxidant gas to an air electrode 13; and a spacer 5 disposed between the cell housing member 2 and the air electrode side separator 4. The spacer 5 is composed of a spacer 51 for manifold configuration and a spacer 52 for adjustment.

Description

  The present invention relates to a solid oxide fuel cell.

  In recent years, high efficiency can be obtained regardless of the size of the scale, and therefore, fuel cells have attracted attention as power generation means used in next-generation cogeneration systems (see, for example, Non-Patent Document 1). A fuel cell is a battery that uses a chemical reaction between an oxidant gas such as oxygen and a fuel gas such as hydrogen. A fuel cell is composed of a single cell with an electrolyte layer sandwiched between an anode called an air electrode and a cathode called a fuel electrode. A plurality are connected in series. The voltage of electricity obtained by one single cell is about 0.7 [V], but a desired voltage can be supplied by connecting a plurality of single cells in series. Such fuel cells include a solid polymer type using a polymer material for the electrolyte layer, and a solid oxide type using an oxide such as ceramics for the electrolyte layer.

  The polymer electrolyte fuel cell has an operating temperature of about 90 [° C.] at most, and can be applied to automobile and household cogeneration systems. On the other hand, the solid oxide fuel cell is characterized in that the operating temperature is as high as 600 [° C.] or higher and the power generation efficiency is as high as 45% or higher. For this reason, a solid oxide fuel cell with a stack structure in which a plurality of single cells are combined has the advantage that a more efficient cogeneration system can be constructed by combining turbine power generation, etc. Expected.

  By the way, when connecting a plurality of single cells in series in order to obtain a practical output in the solid oxide fuel cell as described above, the fuel gas supplied to the fuel electrode side of each single cell and the air electrode side It is necessary to make each single cell electrically connected in a state in which the oxidant gas supplied to is not mixed. For this reason, in order to electrically connect each single cell in a state in which gas mixing is prevented, a member made of a material that does not transmit gas and has high electrical conductivity is used, such as a separator or an interconnector. ing. The separator is disposed on the fuel electrode side of the single cell and supplies the fuel gas to the fuel electrode. The separator is disposed on the air electrode side of the single cell and supplies the oxidant gas to the air electrode. There is an air electrode side separator. The fuel electrode side separator and the air electrode side separator sandwich a cell housing member that houses a single cell, thereby forming one solid oxide fuel cell (hereinafter also referred to as “cell”). Is stacked to form a solid oxide fuel cell stack.

  The fuel electrode side separator and the air electrode side separator have a fuel gas or an oxidant uniformly in the contact surface between the contact portion that protrudes toward the opposing electrode and is in electrical contact with the electrode, and the contact portion of the electrode. A gas flow path for supplying gas is provided. Further, each separator and cell housing member includes a manifold for supplying fuel gas, a manifold for exhausting unused fuel gas and used fuel gas, a manifold for supplying oxidant gas, and a manifold for exhausting oxidant gas. Are also provided. This flow path needs to be connected to the flow path of the adjacent separator or cell housing member without any gap so as not to leak gas flowing inside. Since the contact portion has a shape protruding as described above, the flow path of the separator has a protruding shape.

  In recent years, a metal material can be used for a separator by lowering the power generation temperature. Metal separators have better workability than ceramic separators and high electrical and thermal conductivity, but there is a problem of forming an oxide film with low electrical conductivity on the surface in a high-temperature oxidizing atmosphere. . Therefore, recently, ferritic heat resistant stainless steel containing about 16 to 24% of Cr tends to be used.

Tagawa Hiroaki, Solid Oxide Fuel Cell and Global Environment, Agne Jofusha, 1998, p. 25-30

When the separator is processed by etching, it is possible to accurately form the contact portion and the flow path constituting the manifold, but there is a problem that the cost is increased. On the other hand, when drawing press processing capable of mass production is used, it is possible to reduce the cost of separator processing.
However, since drawing press work has low work accuracy, it has been difficult to form the separator as designed. In particular, if the flow path constituting the manifold cannot be formed as designed, a gap is generated between adjacent manifold components, and fuel gas and oxidant gas leak from the gap. Then, sufficient fuel gas and oxidant gas are not supplied to the single cell, and as a result, the power generation performance of the fuel cell is degraded.

  Then, this invention aims at preventing a gas leak.

  In order to solve the above-described problems, a solid oxide fuel cell according to the present invention includes a fuel electrode, an electrolyte composed of a solid oxide disposed on the fuel electrode, and air disposed on the electrolyte. A single cell comprising electrodes, an opening for accommodating the single cell, an oxidant gas supply manifold formed around the opening and through which an oxidant gas flows, and a fuel gas supply manifold through which the fuel gas flows A plate-shaped cell housing member having through holes constituting a plurality of manifolds, a contact portion arranged to face the fuel electrode side of the single cell housed in the cell housing member, and contacting the fuel electrode, of the contact portion A plate-like shape having a plurality of through holes formed in the periphery and constituting a manifold, and a fuel gas supply passage for supplying fuel gas flowing through the fuel gas supply manifold to the fuel electrode The electrode side separator and the single cell accommodated in the cell accommodating member are arranged to face the air electrode side and are in contact with the air electrode. A plate-like air electrode side separator having a hole and an oxidant gas supply passage for supplying an oxidant gas flowing through the oxidant gas supply manifold to the air electrode; and at least one of a fuel electrode side separator and an air electrode side separator And a manifold-constituting spacer that has a through-hole that constitutes a manifold, and a through-hole that is provided on at least one side of the manifold-constituting spacer in the axial direction of the manifold. And an adjusting spacer having a hole.

  In the solid oxide fuel cell, the adjustment spacer may be formed thinner than the manifold constituting spacer.

  The solid oxide fuel cell stack according to the present invention is a solid oxide fuel cell stack in which a plurality of solid oxide fuel cells are stacked, and the solid oxide fuel cell is the solid oxide fuel cell stack. It consists of a fuel cell.

  Further, the spacer according to the present invention includes a fuel cell, a single cell composed of a solid oxide disposed on the fuel electrode, and an air electrode disposed on the electrolyte, and an opening for accommodating the single cell, And a plate-like cell having a through-hole formed around the opening and constituting a plurality of manifolds including at least an oxidant gas supply manifold through which an oxidant gas flows and a fuel gas supply manifold through which the fuel gas flows. A housing member, and a contact portion that is disposed to face the fuel electrode side of the single cell housed in the cell housing member and contacts the fuel electrode; a plurality of through holes that are formed around the contact portion and constitute a manifold; And a plate-like fuel electrode side separator having a fuel gas supply passage for supplying the fuel gas flowing through the fuel gas supply manifold to the fuel electrode, and housed in the cell housing member The single cell is disposed to face the air electrode side, and is in contact with the air electrode, formed around the contact part, and circulates through the plurality of through holes constituting the manifold and the oxidant gas supply manifold. A spacer used in a solid oxide fuel cell having a plate-shaped air electrode side separator having an oxidant gas supply passage for supplying an oxidant gas to the air electrode, the fuel electrode side separator and the air electrode side A manifold constituting spacer provided between at least one of the separators and the cell housing member and having a through hole constituting the manifold, and provided on at least one side of the manifold constituting spacer in the axial direction of the manifold. And an adjustment spacer having a through-hole.

  According to the present invention, by providing the manifold constituting spacer and the adjusting spacer, it is possible to prevent a gap from being generated in the manifold, and as a result, it is possible to prevent gas leakage.

FIG. 1 is an exploded perspective view showing a configuration of a solid oxide fuel cell according to an embodiment of the present invention. FIG. 2 is a cross-sectional view schematically showing the configuration of the solid oxide fuel cell according to the embodiment of the present invention. FIG. 3 is a perspective view schematically showing the configuration of a single cell. FIG. 4 is a perspective view schematically showing a peripheral configuration of the cell housing member. FIG. 5 is a perspective view schematically showing the configuration of the manifold configuration spacer and the air electrode side flow path plate. FIG. 6 is a diagram showing experimental results of power generation performance of the stack of the solid oxide fuel cell according to the present embodiment and the stack not using the adjustment spacer 52.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

<Configuration of solid oxide fuel cell>
As shown in FIGS. 1 to 3, the solid oxide fuel cell (hereinafter also referred to as “cell”) according to the present embodiment includes a fuel electrode 11 and a solid oxide disposed on the fuel electrode 11. A single cell 1 composed of an electrolyte 12 made of a material and an air electrode 13 disposed on the electrolyte 12, a cell housing member 2 for housing the single cell 1, and a fuel electrode 11 side of the cell housing member 2 A fuel electrode side separator 3 for supplying fuel gas to the fuel electrode 11, an air electrode side separator 4 for stacking on the air electrode 13 side of the cell housing member 2 and supplying an oxidant gas to the air electrode 13, and a cell housing A spacer 5 disposed between the member 2 and the air electrode side separator 4 is provided, and these are configured as one set. The cell housing member 2, the fuel electrode side separator 3 and the air electrode side separator 4 are each formed in a substantially rectangular plate shape in plan view, and at each of the four corners, there are a fuel gas supply manifold, a fuel gas exhaust manifold, The four manifolds of the oxidant gas supply manifold 6 and the oxidant gas exhaust manifold 7 are formed. These manifolds extend along the stacking direction of the cell housing member 2, the fuel electrode side separator 3, and the air electrode side separator 4.

  Such a cell functions as a part of a solid oxide fuel cell stack in which a plurality of cells are stacked in order to obtain a practical output. An external circuit (not shown) for taking out the electric power generated by the solid oxide fuel cell stack is connected to the uppermost and lowermost separators of the solid oxide fuel cell stack.

<Single cell configuration>
As shown in FIG. 3, the single cell 1 sandwiches an electrolyte 12 made of a flat plate-shaped oxide having a circular shape in plan view with a flat plate-shaped fuel electrode 11 having a circular shape in plan view and a flat plate-shaped air electrode 13 having a circular shape in plan view. The current collecting layer 14 is arranged on the air electrode 13.

  Examples of the material of the fuel electrode 11 include a mixture of metal Ni and a material constituting an electrolyte 12 described later. Examples of the mixture include nickel-added yttria-stabilized zirconia (Ni-YSZ), nickel-added samaria-stabilized zirconia (Ni-SSZ), nickel-added scandia-stabilized zirconia (Ni-ScSZ), and the like.

  Examples of the material of the electrolyte 12 include scandia-stabilized zirconia (ScSZ), yttria-stabilized zirconia (YSZ), samaria-stabilized zirconia (SSZ), and cobalt-added lanthanum gallate oxide (LSGMC).

  Examples of the material of the air electrode 13 include lanthanum nickel ferrite (LNF), lanthanum manganate (LSM), lanthanum strontium cobaltite (LSC), lanthanum strontium cobaltite ferrite (LSCF), lanthanum strontium ferrite (LSF), and samarium strontium cobalt. There are tight (SSC) and the like.

≪Configuration of cell housing member≫
The cell housing member 2 sandwiched between the fuel electrode side separator 3 and the air electrode side separator 4 has a laminated structure of a cell holder 21, an insulator 22, and a seal material 23.

As shown in FIG. 4, the planar cell holder 21 having a rectangular shape in plan view has a circular opening 211 formed in the center of the cell holder 21 and a fuel gas supply formed around each of the openings 211. A through hole 101 constituting a manifold, a through hole 102 constituting a fuel gas exhaust manifold, a through hole 103 constituting an oxidant gas supply manifold 6, and a through hole 104 constituting an oxidant gas exhaust manifold 7 are provided. ing. Here, the diameter of the opening 211 is set to be slightly larger than the outer diameter of the single cell 1, and the single cell 1 is disposed in the opening 211. Examples of the material of the cell holder 21 include ferritic stainless steel containing 20 wt% or more of Cr. Of these, SUS445M2, SUS430, and the like are preferable.
The thickness h of the cell holder 21 is such that the height of the contact portion 311a formed on the fuel electrode side flow path plate 31 of the fuel electrode side separator 3 described later is a, the thickness of the current collector 8 described later is t, When the thickness is i, it is desirable to satisfy the following formula (1).

−0.1 mm <h− (a + t−i) <0.1 mm (1)

The planar insulator 22 having a rectangular shape in plan view includes an opening 221 having a substantially circular shape in plan view formed in the center portion, and a through hole 101 forming a fuel gas supply manifold, each formed around the opening 221. The through hole 102 constituting the fuel gas exhaust manifold, the through hole 103 constituting the oxidant gas supply manifold 6, and the through hole 104 constituting the oxidant gas exhaust manifold 7 are provided. Here, the diameter of the opening 221 is set to be slightly larger than the outer diameter of the single cell 1, and the single cell 1 is disposed in the opening 221. Examples of the material of the insulator 22 include alumina (Al ₂ O ₃ ), magnesia (MgO), mica, and the like. It is preferable to arrange a glass seal 222 on the outer periphery of each of the through hole 101 constituting the fuel gas supply manifold of the insulator 22 and the through hole 102 constituting the fuel gas exhaust manifold.

  The flat plate-shaped sealing material 23 having a rectangular shape in plan view includes an opening 231 formed in the center portion and having a substantially circular shape in plan view, and through-holes 101 forming a fuel gas supply manifold formed around the opening 231, respectively. The through hole 102 constituting the fuel gas exhaust manifold, the through hole 103 constituting the oxidant gas supply manifold 6, and the through hole 104 constituting the oxidant gas exhaust manifold 7 are provided. Here, the diameter of the opening 231 is larger than the outer diameter of the air electrode 13, smaller than the outer diameter of the single cell 1 (outer diameter of the electrolyte 12), and smaller than the opening 211 of the cell holder 21 described above. The sealing material 23 is set to be applied to the end of the electrolyte 12 when the solid oxide fuel cell stack is assembled.

Examples of the material for the sealing material 23 include a ferritic stainless steel foil having the same thermal expansion coefficient as that of the electrolyte 12. Among them, ferritic stainless steel containing 2.0 wt% to 4.0 wt% of Al is preferable. The thickness is preferably 10 μm to 50 μm, and more preferably 30 μm. By using ferritic stainless steel having a thermal expansion coefficient equivalent to that of the single cell 1 as the sealing material 23, gas sealing properties can be ensured even during a thermal cycle.
Note that a glass seal (not shown) having a softening point in the range of 600 ° C. to 800 ° C. and a crystallization temperature of 850 ° C. or more is preferably disposed inside the opening 231 of the sealing material 23.

≪Configuration of fuel electrode side separator≫
The fuel electrode side separator 3 has a laminated structure of a fuel electrode side flow path plate 31, a fuel gas flow path plate 32, a fuel gas passage plate 33, and a passage partition plate 34.

  The planar fuel electrode side flow path plate 31 having a rectangular shape in plan view has a fuel gas flow path 311b formed at the center and made up of a contact portion 311a protruding toward the fuel electrode 11 and a recess adjacent to the contact portion 311a. A fuel gas supply unit 311, a fuel gas supply through-hole 312 disposed in the center of the fuel gas supply unit 311, and a fuel disposed slightly outside the outer periphery of the unit cell 1. A gas exhaust through hole 313 is formed. Further, around the fuel gas supply unit 311, a through hole 101 constituting a fuel gas supply manifold, a through hole 102 constituting a fuel gas exhaust manifold, a through hole 103 constituting an oxidant gas supply manifold 6, A through hole 104 constituting the oxidant gas exhaust manifold 7 is formed.

  The flat plate-shaped fuel gas flow path plate 32 having a rectangular shape in plan view includes a through hole 101 constituting a fuel gas supply manifold, a through hole 102 constituting a fuel gas exhaust manifold, and a through hole constituting an oxidant gas supply manifold 6. A through hole 321 disposed in the center so as to communicate with the hole 103, the through hole 104 constituting the oxidant gas exhaust manifold 7, and the through hole 312 of the fuel electrode side flow path plate 31; A through hole 322 for exhausting the fuel gas is formed so as to communicate with the through hole 313 of the fuel electrode side flow path plate 31.

  The flat plate-shaped fuel gas passage plate 33 having a rectangular shape in plan view includes a through hole 101 constituting a fuel gas supply manifold, a through hole 102 constituting a fuel gas exhaust manifold, and a through hole constituting an oxidant gas supply manifold 6. 103, a through hole 104 constituting the oxidant gas exhaust manifold 7 and a position communicating with the through hole for fuel gas supply of the fuel gas flow path plate 32 from a position communicating with the through hole 101 constituting the fuel gas supply manifold From the position communicating with the fuel gas supply passage 331 penetrating the fuel gas passage plate 33 and the fuel gas exhausting through hole of the fuel gas passage plate 32 to the position communicating with the through hole 102 constituting the fuel gas exhaust manifold. Thus, a fuel gas exhaust passage 332 that penetrates the fuel gas passage plate 33 is formed.

  The flat passage partition plate 34 having a rectangular shape in plan view has a through hole 101 constituting a fuel gas supply manifold, a through hole 102 constituting a fuel gas exhaust manifold, and a through hole 103 constituting an oxidant gas supply manifold 6. And a through-hole 104 constituting the oxidant gas exhaust manifold 7 is formed.

≪Configuration of air electrode side separator≫
On the other hand, the air electrode side separator 4 has a laminated structure of an air electrode side flow path plate 41, an oxidant gas flow path plate 42, an oxidant gas path plate 43, and a path partition plate 44.

  The flat plate-shaped air electrode side flow path plate 41 having a rectangular shape in plan view is formed at the center, and includes an oxidant gas flow path 411b including a contact portion 411a protruding toward the air electrode 13 and a recess adjacent to the contact portion 411a. And an oxidant gas supply through hole 412 disposed at the center of the oxidant gas supply part 411. Around the oxidant gas supply unit 411, a through hole 101 constituting a fuel gas supply manifold, a through hole 102 constituting a fuel gas exhaust manifold, and a through hole 103 constituting an oxidant gas supply manifold 6 are provided. A through-hole 104 constituting the oxidant gas exhaust manifold 7 is formed.

  The planar oxidant gas flow path plate 42 having a rectangular shape in plan view includes a through hole 101 constituting a fuel gas supply manifold, a through hole 102 constituting a fuel gas exhaust manifold, and an oxidant gas supply manifold 6. A through hole 103, a through hole 104 constituting the oxidant gas exhaust manifold 7, and an oxidant gas supply through hole 421 arranged so as to communicate with the through hole 412 of the air electrode side flow path plate 41 are formed. Has been.

  The flat plate-shaped oxidant gas passage plate 43 having a rectangular shape in plan view includes a through hole 101 constituting a fuel gas supply manifold, a through hole 102 constituting a fuel gas exhaust manifold, and a through hole constituting an oxidant gas supply manifold 6. A position communicating with the through hole 421 of the oxidant gas flow path plate 42 from a position communicating with the hole 103, the through hole 104 constituting the oxidant gas exhaust manifold 7, and the through hole 103 constituting the oxidant gas supply manifold 6. Thus, an oxidant gas supply passage 431 passing through the oxidant gas passage plate 43 is formed.

  The flat passage partition plate 44 having a rectangular shape in plan view includes a through hole 101 constituting a fuel gas supply manifold, a through hole 102 constituting a fuel gas exhaust manifold, and a through hole 103 constituting an oxidant gas supply manifold 6. And a through-hole 104 constituting the oxidant gas exhaust manifold 7 is formed.

The material for the fuel electrode side separator 3 and the air electrode side separator 4 is preferably a metal, and specifically, for example, ferritic stainless steel containing 20 wt% or more of Cr. All the plates constituting the fuel electrode side separator 3 and the air electrode side separator 4 are formed by punching press processing or drawing press processing.
Specifically, the fuel electrode side flow path plate 31 and the air electrode side flow path plate 41 include a fuel gas supply part 311 including a contact part 311a and an oxidant gas supply part 411 including a contact part 411a by drawing press processing. The through holes 101 to 104 are formed by punching press processing.
On the other hand, the fuel gas passage plate 32, the fuel gas passage plate 33, the passage partition plate 34, the oxidant gas passage plate 42, the oxidant gas passage plate 43, and the passage partition plate 44 are formed by punching press processing. .
The cell holder 21 is formed by punching press processing.

≪Spacer configuration≫
The spacer 5 includes a manifold constituting spacer 51 and an adjusting spacer 52.

As shown in FIG. 5, the manifold constituting spacer 51 is a flat plate having a triangular shape in plan view, and a fuel gas supply manifold, a fuel gas exhaust manifold, an oxidant gas supply manifold 6 or an oxidant gas exhaust manifold 7 is provided at the center. The through-hole 51a which comprises is formed. Similarly, the adjustment spacer 52 is also a flat plate having a triangular shape in plan view similar to the manifold configuration spacer 51, and a through hole 52a configuring the manifold is formed at the center.
The thickness of the manifold-constituting spacer 51 is the height of the drawing press processing performed on the air electrode side flow path plate 41 described above, in other words, the protrusion of the contact portion 411a from the main surface of the air electrode side flow path plate 41. It corresponds to the height (protrusion height). On the other hand, the adjustment spacer 52 is formed thinner than the manifold constituting spacer 51. In the present embodiment, the manifold constituting spacer 51 is formed to have a thickness of about 0.3 to 0.5 mm, and the adjusting spacer 52 is formed to have a thickness of 10 to 50 μm.

The material for the manifold-constituting spacer 51 and the adjusting spacer 52 is preferably metal, and specifically, for example, ferritic stainless steel containing 20 wt% or more of Cr. Examples of the ferritic stainless steel include SUS430 and SUS445M2, among which SUS445M2 is preferable.
The manifold constituting spacer 51 and the adjusting spacer 52 are produced by punching and pressing a metal plate made of such a material.
Such a manifold-constituting spacer 51 is provided between the cell housing member 2 and the air electrode side separator 4, specifically, the through holes 101 to 104 of the sealing material 23 and the air electrode side flow path plates 41. It arrange | positions between the holes 101-104. Further, the adjustment spacer 52 is provided as necessary at least one side of the manifold constituting spacer 51 in the axial direction of the manifold, specifically, between the manifold constituting spacer 51 and the cell housing member 2 or the manifold constitution. It is arranged between the spacer 51 for use and the air electrode side separator 4.

<Cell assembly method>
Next, a procedure for assembling a solid oxide fuel cell using one single cell 1 will be described.

  First, the fuel electrode side separator 3 is prepared. As described above, the fuel electrode side separator 3 includes the passage partition plate 34, the fuel gas passage plate 33 disposed on the passage partition plate 34, and the fuel gas flow disposed on the fuel gas passage plate 33. It has a laminated structure of a path plate 32 and a fuel electrode side flow path plate 31 disposed on the fuel gas flow path plate 32.

  Subsequently, the current collector 8 for improving the electrical connection between the fuel electrode 11 and the fuel electrode side separator 3 is disposed on the surface of the fuel electrode side flow path plate 31 where the fuel gas supply unit 311 is formed. The single cell 1 is mounted on the current collector 8 so that the fuel electrode 11 faces downward. At this time, the unit cell 1 is mounted so that the center thereof coincides with the center of the fuel electrode side separator 3. As the current collector 8, a punching metal or a foam metal that allows fuel gas to pass therethrough is used.

  In addition, a cell holder 21 for housing the single cell 1 is stacked on the same surface of the fuel electrode side flow path plate 31 on which the current collector 8 is mounted. At this time, the single cell 1 is disposed in the through hole 106 of the cell holder 21.

  Subsequently, the insulator 22 is disposed on the cell holder 21, and the sealing material 23 is disposed on the insulator 22. The diameter of the opening 231 of the sealing material 23 is set so that the sealing material 23 is applied to the end portion of the electrolyte 12. In order to suppress the mixing of the fuel gas and the oxidant gas in the cell peripheral portion, a glass seal may be disposed in the gap between the sealing material 23 and the end portion of the single cell 1.

  When the sealing material 23 is disposed, the manifold constituting spacer 51 is disposed on the sealing material 23. The manifold-constituting spacer 51 is disposed on the sealing material 23 so that the through-hole 51 a is continuous with the corresponding through-holes 101 to 104 of the sealing material 23.

Subsequently, if necessary, the adjusting spacer 52 is disposed on the manifold constituting spacer 51 or on the sealing material 23. Also at this time, the adjustment spacer 52 is disposed on the manifold constituting spacer 51 so that the through hole 52a is continuous with the through hole 51a of the manifold constituting spacer 51 and the through holes 101 to 104 of the sealing material 23.
When the contact portion 411a is formed according to the design value, the adjustment spacer 52 is not necessary. However, as described above, the contact portion 411a is formed by drawing press processing, and thus may not be formed according to the design value. is expected. Also, it is expected that other components are not formed as designed. Therefore, an adjustment spacer 52 is inserted between the components of the manifold as necessary.
At this time, the location and the number of the adjustment spacers 52 are arranged such that when the air electrode side separator 4 is placed on the manifold structure spacer 51, the through holes 101 to 104 of the air electrode side flow path plate 41 and the manifold. It is adjusted by the gap generated between the constituent spacers 51. The adjustment spacers 52 are arranged on the manifold constituting spacer 51 in which the gap is generated as many as the gap is filled. Therefore, the adjustment spacer 52 is disposed after the air electrode side separator 4 is mounted on the manifold structure spacer 51 after the air electrode side separator 4 is removed, or the air electrode side separator 4 is disposed on the manifold structure spacer 51. You may make it insert in a clearance gap in the state mounted on top.

  Finally, the air electrode side connection material 9 made of a paste material is disposed on the current collecting layer 14 mounted on the air electrode 13, and then the air electrode is disposed on the air electrode side connection material 9 and the sealing material 23. The side separator 4 is placed. At this time, the air electrode side separator 4 is mounted so that the center thereof coincides with the center of the single cell 1. As described above, the air electrode side separator 4 includes the air electrode side flow channel plate 41, the oxidant gas flow channel plate 42 disposed on the air electrode side flow channel plate 41, and the oxidant gas flow channel plate 42. And an oxidant gas passage plate 43 disposed on the oxidant gas passage plate 43 and a passage partition plate 44 disposed on the oxidant gas passage plate 43.

  Thus, the assembly of the solid oxide fuel cell is completed. When assembling a solid oxide fuel cell stack, a plurality of cells may be stacked.

<Operation of solid oxide fuel cell>
Finally, the operation of the solid oxide fuel cell will be briefly described.

  The oxidant gas flows through the oxidant gas supply manifold 6 and is supplied to the air electrode 13 through the oxidant gas supply passage 431 and the through holes 421 and 412. As described above, the oxidant gas is supplied from the through hole 412 to the central portion of the air electrode 13 of the single cell 1 and flows in the direction of the outer peripheral portion of the single cell 1 through the oxidant gas flow path 411b. The used oxidant gas includes a flow path (not shown) formed in the air electrode side flow path plate 41, a flow path (not shown) formed in the oxidant gas flow path plate 42, and an oxidant gas path. The gas is discharged from the oxidant gas exhaust manifold 7 through a flow path (not shown) formed in the plate 43.

  On the other hand, the fuel gas flows through the fuel gas supply manifold (through hole 101) and is supplied to the fuel electrode 11 through the fuel gas supply passage 331 and the through holes 321 and 312. As described above, the fuel gas is supplied from the through hole 312 to the central portion of the fuel electrode 11 of the single cell 1 and flows in the direction of the outer peripheral portion of the single cell 1 through the fuel gas flow path 311b. The spent fuel gas passes through the through holes 313 and 322 and the fuel gas exhaust passage 332 and is discharged to the outside from the fuel gas exhaust manifold (through hole 102).

Thus, in the manifold through which the fuel gas and oxidant gas essential for the operation of the solid oxide fuel cell circulate, the space between the cell housing member 2 and the air electrode side separator 4, specifically, the sealing material 23 Between the through holes 101 to 104 and the through holes 101 to 104 of the air electrode side flow path plate 41, a manifold configuration spacer 51 and an adjustment spacer 52 are provided.
The separator manifold formed by drawing press processing is not formed according to the design value due to low machining accuracy, so there is a gap between adjacent manifold components, and gas leaks from the gap and a single cell is formed. Insufficient fuel gas or oxidant gas is supplied, and as a result, the power generation performance of the fuel cell may be reduced.
Therefore, in the present embodiment, the thickness corresponding to the protruding height of the contact portion 411a, in other words, the protruding height, between the sealing material 23 and the air electrode side flow path plate 41 so that the gap does not occur. A manifold-constituting spacer 51 having a thickness that matches the design value is disposed, and an adjustment spacer 52 that is thinner than the manifold-constituting spacer 51 is disposed as necessary. Thereby, since it can prevent that a clearance gap generate | occur | produces between the through-holes 101-104 of the sealing material 23, and the through-holes 101-104 of the air electrode side flow path plate 41, the fall of the power generation performance by the gas leak from a manifold is suppressed. be able to.

  FIG. 6 shows the power generation of the stack of the solid oxide fuel cell according to the present embodiment (“with spacer” in FIG. 6) and the stack without the manifold adjusting spacer 52 (“without spacer” in FIG. 6). These are the results of performance experiments, each of which is formed by stacking 10 cells, where the material of the manifold constituting spacer 51 and the adjusting spacer 52 is the same as that of the air electrode side separator 4. Each of these stacks is installed inside an electric furnace, heated to 800 ° C., and when it reaches 800 ° C., hydrogen gas is supplied to the fuel electrode 11 side to form the fuel electrode 11. When the open circuit voltage after reduction was compared, as shown in Fig. 6, the stack of cells according to the present embodiment had an open circuit voltage of 1.830 to 1.1843V. In contrast, the open circuit voltage of the stack not using the manifold adjustment spacer 52 is not stable at 1.0009 to 1.1088 V. Therefore, both the manifold configuration spacer 51 and the adjustment spacer 52 are arranged. By doing this, it is understood that the gas sealing performance of the manifold is good and gas leakage is suppressed.

  As described above, according to the present embodiment, since both the manifold constituting spacer 51 and the adjusting spacer 52 are provided, it is possible to prevent a gap from being generated in the manifold. Can be prevented. Thereby, the fall of the power generation performance of a fuel cell can also be prevented.

  In this embodiment, the case where the manifold-constituting spacer 51 is provided on the air electrode side separator 4 side has been described as an example. However, the position where these spacers are provided is not limited to the air electrode side separator 4 side. It can be set freely as appropriate. For example, it may be provided on the fuel electrode side separator 3 side or on both the fuel electrode side separator 3 side and the air electrode side separator 4 side. Further, the adjustment spacer 52 has been described as being disposed between the seal material 23 and the manifold constituting spacer 51. However, the position of the adjustment spacer 52 is not limited to this as long as it is between the components of the manifold, and can be freely set as appropriate. Can be set to

  The present invention can be applied to a fuel cell stack configured by laminating plate-like separators.

  DESCRIPTION OF SYMBOLS 1 ... Single cell, 2 ... Cell accommodating member, 3 ... Fuel electrode side separator, 4 ... Air electrode side separator, 5 ... Spacer, 6 ... Oxidant gas supply manifold, 7 ... Oxidant gas exhaust manifold, 7 ... Current collector , 8 ... Air electrode side connection material, 11 ... Fuel electrode, 12 ... Electrolytic quality, 13 ... Air electrode, 21 ... Cell holder, 22 ... Insulator, 23 ... Sealing material, 24 ... Spacer, 31 ... Fuel electrode side flow path plate 32 ... Fuel gas passage plate, 33 ... Fuel gas passage plate, 34 ... Passage partition plate, 41 ... Air electrode side passage plate, 42 ... Oxidant gas passage plate, 43 ... Oxidant gas passage plate, 44 ... Passage partition plate, 101-104 ... through hole, 211, 221, 231 ... opening, 222 ... glass seal, 51 ... manifold configuration spacer, 52 ... adjustment spacer, 51a, 52a ... through hole, 311 Fuel gas supply section, 311a ... contact section, 311b ... fuel gas flow path, 312, 313, 321, 322 ... through hole, 331 ... fuel gas supply passage, 332 ... fuel gas exhaust passage, 411 ... oxidant gas supply section, 411a ... contact part, 411b ... oxidant gas flow path, 412,421,431 ... through-hole.

In order to solve the above-described problems, a solid oxide fuel cell according to the present invention includes a fuel electrode, an electrolyte composed of a solid oxide disposed on the fuel electrode, and air disposed on the electrolyte. A single cell comprising electrodes, an opening for accommodating the single cell, an oxidant gas supply manifold formed around the opening and through which an oxidant gas flows, and a fuel gas supply manifold through which the fuel gas flows A plate-shaped cell housing member having through holes constituting a plurality of manifolds, a contact portion arranged to face the fuel electrode side of the single cell housed in the cell housing member, and contacting the fuel electrode, of the contact portion A plate-like shape having a plurality of through holes formed in the periphery and constituting a manifold, and a fuel gas supply passage for supplying fuel gas flowing through the fuel gas supply manifold to the fuel electrode The electrode side separator and the single cell accommodated in the cell accommodating member are arranged to face the air electrode side and are in contact with the air electrode. A plate-like air electrode side separator having a hole and an oxidant gas supply passage for supplying an oxidant gas flowing through the oxidant gas supply manifold to the air electrode; and at least one of a fuel electrode side separator and an air electrode side separator And a manifold-constituting spacer that has a through-hole that constitutes a manifold, and a through-hole that is provided on at least one side of the manifold-constituting spacer in the axial direction of the manifold. an adjusting spacer having a hole, the manifold arrangement for the spacer and the adjustment spacers, the same Fe Consists site stainless steel, and the fuel electrode side separator and the air electrode side separator, and is characterized in Rukoto is comprised of the same ferritic stainless steel.

Further, the spacer according to the present invention includes a fuel cell, a single cell composed of a solid oxide disposed on the fuel electrode, and an air electrode disposed on the electrolyte, and an opening for accommodating the single cell, And a plate-like cell having a through-hole formed around the opening and constituting a plurality of manifolds including at least an oxidant gas supply manifold through which an oxidant gas flows and a fuel gas supply manifold through which the fuel gas flows. A housing member, and a contact portion that is disposed to face the fuel electrode side of the single cell housed in the cell housing member and contacts the fuel electrode; a plurality of through holes that are formed around the contact portion and constitute a manifold; And a plate-like fuel electrode side separator having a fuel gas supply passage for supplying the fuel gas flowing through the fuel gas supply manifold to the fuel electrode, and housed in the cell housing member The single cell is disposed to face the air electrode side, and is in contact with the air electrode, formed around the contact part, and circulates through the plurality of through holes constituting the manifold and the oxidant gas supply manifold. A spacer used in a solid oxide fuel cell having a plate-shaped air electrode side separator having an oxidant gas supply passage for supplying an oxidant gas to the air electrode, the fuel electrode side separator and the air electrode side A manifold constituting spacer provided between at least one of the separators and the cell housing member and having a through hole constituting the manifold, and provided on at least one side of the manifold constituting spacer in the axial direction of the manifold. an adjusting spacer having a through hole which constitutes a manifold configuration for the spacer and the adjusting spacer , Is composed of the same ferritic stainless steel, the fuel electrode side separator and the air electrode side separator, is characterized in that consists of the same ferritic stainless steel.

Claims (4)

A fuel cell, an electrolyte composed of a solid oxide disposed on the fuel electrode, and a single cell composed of an air electrode disposed on the electrolyte;
A plurality of manifolds including at least an opening that accommodates the single cell, an oxidant gas supply manifold that is formed around the opening and through which the oxidant gas flows, and a fuel gas supply manifold through which the fuel gas flows are configured. A plate-like cell housing member having a through hole;
A plurality of through-holes that are disposed to face the fuel electrode side of the single cell housed in the cell housing member and are in contact with the fuel electrode, are formed around the contact part, and constitute the manifold And a plate-like fuel electrode side separator having a fuel gas supply passage for supplying the fuel gas flowing through the fuel gas supply manifold to the fuel electrode,
A plurality of through-holes that are arranged opposite to the air electrode side of the single cell housed in the cell housing member, are in contact with the air electrode, are formed around the contact part, and constitute the manifold. And a plate-shaped air electrode side separator having an oxidant gas supply passage for supplying the oxidant gas flowing through the oxidant gas supply manifold to the air electrode,
A manifold-constituting spacer provided between at least one of the fuel electrode-side separator and the air electrode-side separator and the cell housing member, and having a through-hole constituting the manifold;
A solid oxide fuel cell comprising: an adjustment spacer provided on at least one side of the manifold constituting spacer in the axial direction of the manifold and having a through hole constituting the manifold. The solid oxide fuel cell according to claim 1, wherein
The adjustment spacer is formed thinner than the manifold constituting spacer. A solid oxide fuel cell, wherein: A solid oxide fuel cell stack in which a plurality of solid oxide fuel cells are stacked,
The solid oxide fuel cell comprises the solid oxide fuel cell according to claim 1 or 2. The solid oxide fuel cell stack according to claim 1 or 2. A fuel cell, an electrolyte composed of a solid oxide disposed on the fuel electrode, and a single cell composed of an air electrode disposed on the electrolyte;
A plurality of manifolds including at least an opening that accommodates the single cell, an oxidant gas supply manifold that is formed around the opening and through which the oxidant gas flows, and a fuel gas supply manifold through which the fuel gas flows are configured. A plate-like cell housing member having a through hole;
A plurality of through-holes that are disposed to face the fuel electrode side of the single cell housed in the cell housing member and are in contact with the fuel electrode, are formed around the contact part, and constitute the manifold And a plate-like fuel electrode side separator having a fuel gas supply passage for supplying the fuel gas flowing through the fuel gas supply manifold to the fuel electrode,
A plurality of through-holes that are arranged opposite to the air electrode side of the single cell housed in the cell housing member, are in contact with the air electrode, are formed around the contact part, and constitute the manifold. And a plate-shaped air electrode side separator having an oxidant gas supply passage for supplying the oxidant gas flowing through the oxidant gas supply manifold to the air electrode. Spacers,
A manifold-constituting spacer provided between at least one of the fuel electrode-side separator and the air electrode-side separator and the cell housing member, and having a through-hole constituting the manifold;
A spacer comprising: an adjustment spacer provided on at least one side of the manifold constituting spacer in the axial direction of the manifold and having a through hole constituting the manifold.