JP2016085919A - Fuel battery module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fuel battery module capable of solving a problem that the reliability of equipment is degraded because of non-uniformity of local cell temperature in an SOFC cartridge.SOLUTION: A fuel battery module has plural cells 101, plural flow paths through which fuel gas flows being formed in each cell, and plural upper side cores which are arranged in respective areas at the upstream side of the plural flow paths. The plural cells 101 contain plural end side cells 6 and plural center side cells 7. The upper side cores of the plural center side cells 7 are shorter than the upper side cores of the plural end side cells 6 so that the reforming reaction amount of fuel gas at the upper lead portion 8 at which the upper side cores of the plural center side cells 7 are arranged is smaller than the reforming reaction amount of the fuel gas at the upper lead portion 8 where the upper side cores of the plural end side cells 6 are arranged.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a fuel cell module.

  A fuel cell is a power generation device that uses a power generation method based on an electrochemical reaction, and has excellent power generation efficiency and environmental characteristics. For this reason, as a city gas type energy supply system for the 21st century, research and development for practical use is progressing. Among these, solid oxide fuel cells (SOFC) use ceramics such as zirconia ceramics as an electrolyte, and are operated using city gas, natural gas, petroleum, methanol, coal gasification gas, or the like as fuel. This is a fuel cell.

  FIG. 8 is a schematic configuration diagram showing a one-through type fuel cell cartridge which is an example of a conventional fuel cell. In FIG. 8, the structure related to preheating and heat exchange of various gases used for the operation of the fuel cell and the structure related to collecting the generated power are omitted. The one-through type fuel cell is a type of fuel cell in which the fuel gas supplied from one end of the cell tube is discharged from the other end of the cell in the fuel gas flow method.

  As shown in the figure, the fuel cell 301 includes a plurality of cylindrical cells 302 (three are shown in the figure), a supply chamber 303 a for supplying fuel gas 304 to the cells 302, and fuel discharged from the cells 302. A discharge chamber 303b for discharging the gas 305 and an oxidant supply chamber 325 to which an oxidizing gas 306 is supplied.

  The upper tube plate 321 and the lower tube plate 322 are provided with holes through which the cells 302 are passed, and the cells 302 are supported by passing the cells 302 through the holes, and the supply chamber 303a, the discharge chamber 303b, and the oxidant supply chamber. 325 is isolated. Further, the upper support 323 and the lower support 324 support the cell 302 as an auxiliary. The cylindrical cell 302 is made of a porous material, and a plurality of fuel cells 308 are formed on the outer peripheral surface thereof. Note that a fuel cell may be configured by providing only one element of the fuel cell 308 on the outer surface of the cell 302. This type of fuel cell is referred to as a single element type fuel cell.

  When power is generated by the fuel cell 301, hydrogen, methane, or the like is supplied from the supply chamber 303 a to the inside of the cell 302 as the fuel gas 304, and oxygen, air, or the like is supplied to the outer peripheral surface of the cell 302 as the oxidant gas 306. . Further, by setting the inside of the fuel cell 301 to a high temperature environment of about 800 ° C. to 1000 ° C., the fuel gas 304 and the oxidant gas 306 react electrochemically in the fuel cell 308 to generate power.

The operating temperature of the fuel cell is an extremely high temperature environment of 800 ° C to 1000 ° C. Cores 313 are installed at both ends of the cell 302 in order to effectively exchange heat in the fuel cell 301 and effectively use the heat generated in the fuel cell 301.
A core 313 installed on the upper side of the cell 302 is installed to promote heat exchange between the fuel gas 304 and the exhaust oxidizing gas 307. That is, the fuel gas 304 is a laminar flow in the cell, and is installed to increase heat transfer per unit area and increase the heat transfer area as the flow path is narrower. On the upper side of the cell 302, the fuel gas 304 is steam-reformed and supplies a hydrogen-rich gas to the power generation chamber. The steam reforming reaction is an endothermic reaction, and the amount of heat of the exhaust oxidizing gas 307 is used for the reforming endotherm of the fuel gas 304 and the temperature increase of the fuel gas 304.
The core 313 installed on the lower side of the cell 302 is installed to promote heat exchange between the exhaust fuel gas 305 and the oxidizing gas 306. That is, the exhaust fuel gas 305 is a laminar flow in the cell, and is installed in order to improve heat transfer per unit area and increase the heat transfer area as the flow path is narrower. On the lower side of the cell 302, the amount of heat of the exhaust fuel gas 305 is used to raise the temperature of the oxidizing gas 306.

JP 2004-127640 A

  When the SOFC module output is changed with time, such as when the SOFC module is started or during partial load operation, the temperature of each cell becomes locally non-uniform. When the module temperature becomes non-uniform, the output of the cell with the lowered temperature is reduced, so that other cells on the parallel circuit generate power with a high output. As a result, the amount of heat generated in the low-power cell is reduced, so that the local low-temperature region in the module is expanded. On the other hand, the high-power cell increases the amount of heat generation, so that the local high-temperature region in the module is expanded. When such SOFC module temperature instability occurs, the local temperature difference in the SOFC module progresses in an increasing direction, eventually resulting in overheating of the cell, fuel deficiency, and oxygen deficiency, resulting in damage to the cell. The SOFC module cannot be stably operated, and the reliability of the device is reduced. Patent Document 1 describes the effective use of heat generated inside the fuel cell using the core provided inside the cell tube as described above. It is not clear about the stabilization structure.

  It is an object of the present invention to provide a module structure in which the temperature inside a module is equalized in order to improve the reliability of the SOFC module.

In order to solve the above problems, the fuel cell module of the present invention employs the following means.
The fuel cell module according to the present invention includes a cell in which a fuel gas flow path is formed, and a core disposed in the flow path. The cell includes an end cell and a center cell arranged so as to be surrounded by the end cell. In the end side cell, the center side cell and the core of the end side cell are configured so that the reforming of fuel proceeds from the center side cell.

  Since the center side cell is surrounded by the end side cell, the center side cell is heated by the radiant heat of the end side cell, and the center cell has the highest temperature. By reducing the reforming rate of the core structure of the central cell on the upper side of the cell from the end side cell, the fuel cell module suppresses the maximum temperature by reforming heat absorption of the fuel at the place where the cell exhibits the maximum temperature. Can be made uniform in temperature distribution. As a result, the temperature distribution in the power generation chamber of the fuel cell module is made uniform, stable power generation is possible, and the reliability of the device can be improved.

  The length of the region where the core is disposed among the flow paths of the plurality of center-side cells is shorter than the length of the region where the core is disposed among the flow paths of the plurality of end-side cells. The core of the center side cell is shorter in the longitudinal direction of the flow path than the core of the end side cell.

  In such a fuel cell module, the center side cell core is shorter than the end side cell core, so that the fuel reforming amount in the region where the end side cell core is disposed is larger than the fuel reforming amount in the center side cell. The amount of fuel reforming in the region where the core of the cell is arranged is reduced. As a result, such a fuel cell module increases the temperature of the central cell by extending the fuel reforming region of the central cell to the downstream side of the fuel flow from the fuel reforming region of the end cell. The temperature distribution in the power generation chamber can be made uniform.

  Among the flow paths of the plurality of center side cells, the gap between the cell and the core in the area where the core is arranged is larger than the gap between the areas where the core is arranged in the flow path of the plurality of end side cells. The large, that is, the core of the center side cell has a smaller outer diameter than the core of the end side cell.

  The outer diameter of the core of such a fuel cell module is smaller in the center cell than in the end cell, so heat transfer from the exhaust gas from the upper cell side to the fuel gas is suppressed in the center cell. , Promoted in the end cell. As a result, in the end cell, the reforming of the fuel proceeds more than the center cell, and the cell absorbs heat at the center cell portion where the maximum temperature is reached, so the temperature rise in the power generation chamber is suppressed by suppressing the temperature rise in the center cell. Can be made uniform.

  The core of the end side cell has a plurality of or integral fins on the outer peripheral surface of the core facing the inner surface of the cell.

  Since such a fuel cell module has fins on the outer peripheral surface of the core of the end cell, the heat transfer area from the exhaust gas to the fuel gas in the end cell is expanded. That is, heat transfer from the exhaust oxidizing gas to the fuel gas is suppressed in the center side cell and promoted in the end side cell. As a result, by providing fins on the outer peripheral surface of the cylindrical portion of the core portion of the end side cell, the fuel reforming reaction is promoted in the region where the core is disposed, and is downstream from the core of the end side cell. The reliability of the SOFC module device can be improved by increasing the temperature of the side region and soaking the fuel cell module.

  In the core of the end side cell, a catalyst for reforming reaction is disposed on the outer peripheral surface facing the inner peripheral surface of the cell.

  Such a fuel cell module effectively modifies the fuel gas flowing through the gap between the end cell and the core by applying a reforming reaction catalyst to the outer peripheral surface of the core of the end cell. Quality. As a result, in the end cell, the reforming of fuel proceeds more than in the center cell, the temperature of the end cell of the fuel cell module is increased, and the temperature of the fuel cell module is equalized, thereby improving the reliability of the SOFC module device. It can be improved.

  The fuel cell module according to the present invention can make the temperature distribution in the power generation chamber of the fuel cell module uniform and improve the reliability of the SOFC module device.

It is a disassembled perspective view which shows a fuel cell module. It is sectional drawing which shows a SOFC cartridge. It is sectional drawing which shows a cell. It is a longitudinal cross-sectional view which shows a cell and an upper side core. It is a top view which shows a cell and an upper side core. It is sectional drawing which shows the SOFC cartridge in 1st Embodiment. It is sectional drawing which shows the SOFC cartridge in 2nd Embodiment. It is sectional drawing which shows an example of the conventional fuel cell.

Hereinafter, a fuel cell module according to an embodiment of the present invention will be described with reference to the drawings.
[First Embodiment]
As shown in FIG. 6, the fuel cell module according to the first embodiment is such that the length of the upper core inserted into the base tube 103 of the plurality of center side cells 7 is the base tube of the plurality of end side cells 6. It is formed so that it may become shorter than the length of the upper side core inserted in 103.
As shown in FIG. 1, the fuel cell module 201 includes, for example, a plurality of SOFC cartridges 203 and a pressure vessel 205 that stores the plurality of SOFC cartridges 203. The fuel cell module 201 has a fuel gas supply pipe 207 and a plurality of fuel gas supply branch pipes 207a. The fuel cell module 201 has a fuel gas discharge pipe 209 and a plurality of fuel gas discharge branch pipes 209a. The fuel cell module 201 further includes an oxidizing gas supply pipe, a plurality of oxidizing gas supply branch pipes, an oxidizing gas discharge pipe, and a plurality of oxidizing gas discharge branch pipes (not shown).

  The fuel gas supply pipe 207 is provided outside the pressure vessel 205 and is connected to a fuel gas supply unit (not shown) that supplies a predetermined gas composition and a predetermined flow rate of fuel gas corresponding to the amount of power generated by the fuel cell module 201. And connected to a plurality of fuel gas supply branch pipes 207a. The fuel gas supply pipe 207 is configured to branch and guide a predetermined flow rate of fuel gas supplied from the fuel gas supply unit described above to a plurality of fuel gas supply branch pipes 207a. The fuel gas supply branch pipe 207 a is connected to the fuel gas supply pipe 207 and is connected to a plurality of SOFC cartridges 203. The fuel gas supply branch pipe 207a guides the fuel gas supplied from the fuel gas supply pipe 207 to the plurality of SOFC cartridges 203 at a substantially equal flow rate, and makes the power generation performance of the plurality of SOFC cartridges 203 substantially uniform.

  The fuel gas discharge branch pipe 209a is connected to the plurality of SOFC cartridges 203 and to the fuel gas discharge pipe 209. The fuel gas discharge branch pipe 209a guides the exhaust fuel gas discharged from the SOFC cartridge 203 to the fuel gas discharge pipe 209. The fuel gas discharge pipe 209 is connected to a plurality of fuel gas discharge branch pipes 209 a and a part thereof is disposed outside the pressure vessel 205. The fuel gas discharge pipe 209 guides the exhaust fuel gas led out from the fuel gas discharge branch pipe 209 a at a substantially equal flow rate to the outside of the pressure vessel 205.

  Since the pressure vessel 205 is operated at an internal pressure of 0.1 MPa to about 1 MPa and an internal temperature of the atmospheric temperature to about 550 ° C., the pressure vessel 205 has a resistance to corrosion and resistance to oxidizing agents such as oxygen contained in the oxidizing gas. The possessed material is used. For example, a stainless steel material such as SUS304 is suitable.

  Here, in the present embodiment, a mode has been described in which a plurality of SOFC cartridges 203 are assembled and accommodated in the pressure vessel 205. However, the present invention is not limited to this, and for example, the pressure vessel 205 without collecting the SOFC cartridges 203 is described. It is good also as an aspect accommodated in.

  As shown in FIG. 2, the SOFC cartridge 203 includes a plurality of cells 101, a power generation chamber 215, a fuel gas supply chamber 217, a fuel gas discharge chamber 219, an oxidizing gas supply chamber 221, an oxidizing gas A gas discharge chamber 223 is provided. The SOFC cartridge 203 includes an upper tube plate 225a, a lower tube plate 225b, an upper heat insulator 227a, and a lower heat insulator 227b.

  The power generation chamber 215 is an area formed between the upper heat insulator 227a and the lower heat insulator 227b. The power generation chamber 215 is an area where the fuel cells 105 of the plurality of cells 101 are arranged, and electricity is generated by electrochemically reacting the fuel gas and the oxidizing gas. Further, the temperature in the vicinity of the center in the longitudinal direction of the plurality of cells 101 in the power generation chamber 215 is a high temperature atmosphere of about 700 ° C. to 1000 ° C. during the steady operation of the fuel cell module 201.

  The fuel gas supply chamber 217 is an area surrounded by the upper casing 229a and the upper tube plate 225a of the SOFC cartridge 203. The fuel gas supply chamber 217 communicates with the fuel gas supply branch pipe 207a through a fuel gas supply hole 231a formed in the upper casing 229a. In the fuel gas supply chamber 217, one end of the plurality of cells 101 is disposed with the inside of the base tube 103 of the plurality of cells 101 open to the fuel gas supply chamber 217. The fuel gas supply chamber 217 guides the fuel gas supplied from the fuel gas supply branch pipe 207a through the fuel gas supply hole 231a to the inside of the base tube 103 of the plurality of cells 101 at a substantially uniform flow rate. The power generation performance of 101 is made substantially uniform.

  The fuel gas discharge chamber 219 is an area surrounded by the lower casing 229b and the lower tube plate 225b of the SOFC cartridge 203. The fuel gas discharge chamber 219 communicates with the fuel gas discharge branch pipe 209a through a fuel gas discharge hole 231b formed in the lower casing 229b. Further, in the fuel gas discharge chamber 219, the other end of the plurality of cells 101 is disposed with the inside of the base tube 103 of the plurality of cells 101 open to the fuel gas discharge chamber 219. The fuel gas discharge chamber 219 collects the exhaust fuel gas that passes through the inside of the base tube 103 of the plurality of cells 101 and is discharged into the fuel gas discharge chamber 219, and discharges the fuel gas through the fuel gas discharge hole 231b. It leads to the branch pipe 209a.

  An oxidizing gas is supplied to the oxidizing gas supply pipe from the outside, and a predetermined gas composition and a predetermined flow of oxidizing gas corresponding to the amount of power generated by the fuel cell module 201 are branched into a plurality of oxidizing gas supply branch pipes. Then, it is supplied to a plurality of SOFC cartridges 203. The oxidizing gas supply chamber 221 is a region surrounded by the lower casing 229b, the lower tube sheet 225b, and the lower heat insulator 227b of the SOFC cartridge 203. Further, the oxidizing gas supply chamber 221 is communicated with a plurality of oxidizing gas supply branch pipes through an oxidizing gas supply hole 233a provided in the lower casing 229b. The oxidizing gas supply chamber 221 supplies a predetermined flow rate of oxidizing gas supplied from a plurality of oxidizing gas supply branches through the oxidizing gas supply hole 233a to the power generation chamber 215 through the oxidizing gas supply gap 235a. Lead to.

  The oxidizing gas discharge chamber 223 is a region surrounded by the upper casing 229a, the upper tube plate 225a, and the upper heat insulator 227a of the SOFC cartridge 203. Further, the oxidizing gas discharge chamber 223 is communicated with a plurality of oxidizing gas discharge branch pipes through an oxidizing gas discharge hole 233b provided in the upper casing 229a. The oxidizing gas discharge chamber 223 allows the exhaust oxidizing gas supplied from the power generation chamber 215 to the oxidizing gas discharge chamber 223 via an oxidizing gas discharge gap 235b described later via the oxidizing gas discharge hole 233b. Lead to multiple oxidizing gas outlet branches. The plurality of oxidizing gas discharge branches communicates with the oxidizing gas discharge pipe. The oxidizing gas discharge pipe exhausts the exhaust oxidizing gas discharged from the plurality of oxidizing gas discharge branch pipes to the outside.

  The upper tube plate 225a is arranged between the top plate of the upper casing 229a and the upper heat insulator 227a so that the upper tube plate 225a, the top plate of the upper casing 229a and the upper heat insulator 227a are substantially parallel to each other. Fixed to the side plate. The upper tube sheet 225a has a plurality of holes corresponding to the number of the plurality of cells 101 provided in the SOFC cartridge 203, and the plurality of cells 101 are inserted into the holes. The upper tube sheet 225a hermetically supports one end of the plurality of cells 101 via one or both of a sealing member and an adhesive member, and also includes a fuel gas supply chamber 217, an oxidizing gas discharge chamber 223, Isolate.

  The lower tube plate 225b is disposed on the side plate of the lower casing 229b so that the lower tube plate 225b, the bottom plate of the lower casing 229b, and the lower heat insulator 227b are substantially parallel between the bottom plate of the lower casing 229b and the lower heat insulator 227b. Fixed. The lower tube sheet 225b has a plurality of holes corresponding to the number of the plurality of cells 101 provided in the SOFC cartridge 203, and the plurality of cells 101 are inserted into the holes. The lower tube sheet 225b hermetically supports the other end of the plurality of cells 101 via one or both of a seal member and an adhesive member, and also includes a fuel gas discharge chamber 219, an oxidizing gas supply chamber 221, Isolate.

  The upper heat insulator 227a is disposed at the lower end of the upper casing 229a so that the upper heat insulator 227a, the top plate of the upper casing 229a, and the upper tube plate 225a are substantially parallel to each other, and is fixed to the side plate of the upper casing 229a. . Further, the upper heat insulator 227a is provided with a plurality of holes corresponding to the number of the plurality of cells 101 provided in the SOFC cartridge 203. The diameter of this hole is set larger than the outer diameter of the plurality of cells 101. The upper heat insulator 227a has an oxidizing gas discharge gap 235b formed between the inner surface of this hole and the outer surfaces of the plurality of cells 101 inserted through the upper heat insulator 227a.

  The upper heat insulator 227a separates the power generation chamber 215 and the oxidizing gas discharge chamber 223, and reduces the strength caused by the upper tube sheet 225a becoming high temperature and corrosion caused by the oxidizing agent contained in the oxidizing gas. Suppress.

  According to this embodiment, due to the structure of the SOFC cartridge 203 described above, the fuel gas and the oxidizing gas flow to face the inside and the outside of the plurality of cells 101. As a result, the exhaust oxidizing gas exchanges heat with the fuel gas supplied to the power generation chamber 215 through the inside of the base tube 103, and the upper tube sheet 225a and the like are not deformed such as buckling. It is cooled and discharged to the oxidizing gas discharge chamber 223. In addition, the temperature of the fuel gas is raised by heat exchange with the exhaust oxidizing gas discharged from the power generation chamber 215 and supplied to the power generation chamber 215. As a result, the fuel gas heated to a temperature suitable for power generation can be supplied to the power generation chamber 215 without using a heater or the like.

  The lower heat insulator 227b is disposed at the upper end of the lower casing 229b so that the lower heat insulator 227b, the bottom plate of the lower casing 229b, and the lower tube plate 225b are substantially parallel to each other, and is fixed to the side plate of the lower casing 229b. Also, the lower heat insulator 227b is provided with a plurality of holes corresponding to the number of the plurality of cells 101 provided in the SOFC cartridge 203. The diameter of this hole is set larger than the outer diameter of the plurality of cells 101. The lower heat insulator 227b has an oxidizing gas supply gap 235a formed between the inner surface of this hole and the outer surfaces of the plurality of cells 101 inserted through the lower heat insulator 227b.

  The lower heat insulator 227b separates the power generation chamber 215 and the oxidizing gas supply chamber 221, and reduces the strength due to the lower temperature of the lower tube sheet 225b and the corrosion caused by the oxidizing agent contained in the oxidizing gas. Suppress.

  According to this embodiment, due to the structure of the SOFC cartridge 203 described above, the fuel gas and the oxidizing gas flow to face the inside and the outside of the plurality of cells 101. As a result, the exhaust fuel gas that has passed through the power generation chamber 215 through the inside of the base tube 103 is heat-exchanged with the oxidizing gas supplied to the power generation chamber 215, and the lower tube sheet 225b and the like are buckled. After being cooled to a temperature that does not cause deformation, the fuel gas discharge chamber 219 is supplied. The oxidizing gas is heated by heat exchange with the exhaust fuel gas and supplied to the power generation chamber 215. As a result, the oxidizing gas heated to the temperature required for power generation can be supplied to the power generation chamber 215 without using a heater or the like.

  The direct current power generated in the power generation chamber 215 is led out to the vicinity of the ends of the plurality of cells 101 by the lead film 115 made of Ni / YSZ or the like provided in the plurality of fuel cells 105, and then the current collecting rod (SOFC cartridge 203) The current is collected on a current collector plate (not shown) via a current collector plate (not shown) and taken out of each SOFC cartridge 203. The electric power derived to the outside of the SOFC cartridge 203 by the current collector rod is connected to the generated power of each SOFC cartridge 203 in a predetermined series number and parallel number, and is derived to the outside of the fuel cell module 201. It is converted into predetermined AC power by an inverter (not shown) or the like and supplied to the power load. The inverter controls the output of the current flowing from the fuel cell module 201 to a predetermined current.

  As shown in FIG. 3, the plurality of cells 101 are formed between a cylindrical base tube 103, a plurality of fuel cells 105 formed on the outer peripheral surface of the base tube 103, and adjacent fuel cells 105. Interconnector 107. The fuel cell 105 is formed by stacking a fuel electrode 109, a solid electrolyte 111, and an air electrode 113. Further, among the plurality of fuel cells 105 formed on the outer peripheral surface of the base tube 103, the plurality of cells 101 are arranged on the air electrode 113 of the fuel cell 105 formed at the end in the axial direction of the base tube 103. The lead film 115 is electrically connected through the interconnector 107.

The base tube 103 is made of a porous material, and is made of, for example, CaO stabilized ZrO ₂ (CSZ), Y ₂ O ₃ stabilized ZrO ₂ (YSZ), or MgAl ₂ O ₄ . The base tube 103 supports the fuel battery cell 105, the interconnector 107, and the lead film 115, and supplies the fuel gas supplied to the inner peripheral surface of the base tube 103 through the pores of the base tube 103. Is diffused to the fuel electrode 109 formed on the outer peripheral surface of the electrode.

The fuel electrode 109 is made of an oxide of a composite material of Ni and a zirconia-based electrolyte material. For example, Ni / YSZ is used. In this case, in the fuel electrode 109, Ni that is a component of the fuel electrode 109 has a catalytic action on the fuel gas. This catalytic action reacts with a fuel gas supplied through the base tube 103, for example, a mixed gas of methane (CH ₄ ) and water vapor, and reforms it into hydrogen (H ₂ ) and carbon monoxide (CO). . Further, the fuel electrode 109 has an interface between the solid electrolyte 111 and hydrogen (H ₂ ) and carbon monoxide (CO) obtained by reforming and oxygen ions (O ²⁻ ) supplied via the solid electrolyte 111. It reacts electrochemically in the vicinity to produce water (H ₂ O) and carbon dioxide (CO ₂ ). At this time, the fuel cell 105 generates electric power by electrons emitted from oxygen ions.

The solid electrolyte 111 is mainly made of YSZ having gas tightness that prevents gas from passing through and high oxygen ion conductivity at high temperatures. The solid electrolyte 111 moves oxygen ions (O ²⁻ ) generated at the air electrode to the fuel electrode.

The air electrode 113 is made of, for example, a LaSrMnO ₃ oxide or a LaCoO ₃ oxide. The air electrode 113 generates oxygen ions (O ²⁻ ) by dissociating oxygen in an oxidizing gas such as air supplied near the interface with the solid electrolyte 111.

The interconnector 107 is composed of a conductive perovskite oxide represented by M _1-x L _x TiO ₃ (M is an alkaline earth metal element, L is a lanthanoid element) such as SrTiO ₃ system, and is composed of fuel gas and oxidation It is a dense film so that it does not mix with sex gases. Further, the interconnector 107 has stable electrical conductivity in both an oxidizing atmosphere and a reducing atmosphere. The interconnector 107 electrically connects the air electrode 113 of one fuel battery cell 105 and the solid electrolyte 111 of the other fuel battery cell 105 in adjacent fuel battery cells 105, so that the adjacent fuel battery cells 105 are connected to each other. Are connected in series. Since the lead film 115 needs to have electronic conductivity and a thermal expansion coefficient close to other materials constituting the plurality of cells 101, Ni such as Ni / YSZ and a zirconia-based electrolyte material can be used. It is composed of a composite material. The lead film 115 guides the DC power generated by the plurality of fuel cells 105 connected in series by the interconnector to the vicinity of the end portions of the plurality of cells 101.

  The fuel cell module 201 further includes a plurality of upper side cores corresponding to the plurality of cells 101. As shown in FIG. 4, each upper-side core 1 of the plurality of upper-side cores includes a cylinder portion 2 and a lid portion 3. The cylindrical portion 2 is formed in a cylindrical shape from metal or the like, and the lid portion 3 is formed in a disk shape from metal or the like. An example of the metal is stainless steel. The lid part 3 is joined to one end of the cylinder part 2 so as to close one end of the cylinder part 2. The upper core 1 further includes a plurality of claws 5. As shown in FIG. 5, the plurality of claws 5 protrude radially outward from the cylindrical portion 2, and are attached to the end where the lid portion 3 of the cylindrical portion 2 is joined.

  As shown in FIG. 4, the upper core 1 is arranged inside the base tube 103 of one cell corresponding to the upper core 1 of the plurality of cells 101, The fuel gas supply chamber 217 is disposed in an upstream end region close to the fuel gas supply chamber 217. Further, the upper core 1 is arranged such that the axis of the cylinder part 2 overlaps the axis of the base tube 103 and the end to which the lid part 3 of the cylinder part 2 is joined is located above. The gap between the outer peripheral surface of the upper core 1 and the inner peripheral surface of the base tube 103 is preferably narrow in order to improve heat transfer with the fuel gas. For example, the base tube has a gap of 2 to 3 mm. 103 is arranged inside. The upper core 1 is supported by the base tube 103 by, for example, the plurality of claws 5 being caught on the end of the base tube 103 on the fuel gas supply chamber 217 side. The upper core 1 is disposed inside the base tube 103, thereby forming the upper lead portion 8 in the portion of the base tube 103 of the plurality of cells 101 where the upper core 1 is disposed.

  As shown in FIG. 6, the plurality of cells 101 includes a plurality of end side cells 6 and a plurality of center side cells 7. The plurality of end side cells 6 are arranged at the end of the plurality of SOFC cartridges 203. The plurality of center-side cells 7 are disposed on the center side of the plurality of SOFC cartridges 203 and are disposed so as to be surrounded by the plurality of end-side cells 6.

  The upper core 1 disposed in the base tube 103 of the plurality of center side cells 7 is shorter than the upper core 1 disposed in the plurality of end side cells 6. It is formed. That is, the upper lead portions 8 of the plurality of center side cells 7 are formed to be shorter than the upper lead portions 8 of the plurality of end side cells 6.

With the configuration described above, the present embodiment has the following operational effects.
The fuel cell module 201 supplies a mixed gas of fuel gas and water vapor to the fuel gas supply chamber 217 via the fuel gas supply pipe 207 and the plurality of fuel gas supply branch pipes 207 a, whereby the base of the plurality of cells 101 is provided. A mixed gas is supplied to the flow path inside the tube 103. The fuel cell module 201 further supplies the oxidizing gas to the oxidizing gas supply chamber 221 via the oxidizing gas supply pipe and the plurality of oxidizing gas supply branch pipes, whereby the base tubes 103 of the plurality of cells 101 are supplied. An oxidizing gas is supplied to the power generation chamber 215 on the outside.

The plurality of cells 101 supply the mixed gas of fuel gas and water vapor to the inside of the base tube 103, thereby causing the following chemical reaction formula at the upper lead portion 8 of the base tube 103:
CH ₄ + 2H ₂ O → 4H ₂ + CO
The reforming reaction expressed by is advanced to generate hydrogen (H ₂ ) and carbon monoxide (CO). In the base tube 103, a region 11 for reforming the fuel gas that has not undergone the reforming reaction in the upper lead portion 8 is formed on the downstream side of the upper lead portion 8. Since the reforming reaction is an endothermic reaction, an increase in temperature is suppressed in the power generation chamber 215.

The plurality of cells 101 electrochemically reacts hydrogen (H ₂ ) and carbon monoxide (CO) obtained by the reforming reaction with oxygen ions (O ²⁻ ) supplied to the power generation chamber 215 to form water ( H ₂ O) and carbon dioxide (CO ₂ ) are generated and generated. The temperature of the base tube 103 rises because this reaction is an exothermic reaction. After the temperature rises, the base tube 103 heats another adjacent base tube 103 by radiant heat. For this reason, the plurality of center-side cells 7 surrounded by the plurality of end-side cells 6 are heated by radiation, so that the temperature rises from the plurality of end-side cells 6. The exhaust fuel gas discharged from the base tube 103 is supplied to the fuel gas discharge chamber 219 and is discharged from the fuel gas discharge chamber 219 via the plurality of fuel gas discharge branch pipes 209a and the fuel gas discharge pipe 209.

  The exhaust oxidizing gas that has flowed through the power generation chamber 215 exchanges heat with the mixed gas through the base tube 103 in the upper lead portion 8 where the upper core 1 of the base tubes 103 of the plurality of cells 101 is disposed. The sensible heat reduction of the exhaust oxidizing gas is converted into the reformed endotherm and sensible heat increase of the mixed gas. The exhaust oxidizing gas whose temperature has been lowered at the upper lead portion 8 of the base tube 103 is supplied to the oxidizing gas discharge chamber 223. The exhaust oxidizing gas supplied to the oxidizing gas discharge chamber 223 is exhausted through a plurality of oxidizing gas exhaust branch pipes and an oxidizing gas exhaust pipe.

  Since the upper core 1 is disposed inside the base tube 103, the representative diameter of the fuel gas flow path formed in the upper lead portion 8 is smaller than the representative diameter of the power generation chamber 215 (of the upper lead portion 8). The representative diameter is defined by the difference between the inner diameter of the base tube 103 and the outer diameter of the upper core 1. The representative diameter of the power generation chamber is equal to the inner diameter of the base tube 103). The base tube 103 has a small representative diameter of the flow path of the upper lead portion 8, thereby improving heat transfer per unit area of the upper lead portion 8 of the base tube 103, and heat transfer of the upper lead portion 8 of the base tube 103. Will improve. The base tube 103 improves heat exchange between the fuel gas flowing in the flow path of the upper lead portion 8 and the oxidizing gas flowing outside the upper lead portion 8 by improving the heat transfer of the upper lead portion 8, thereby generating power. The temperature of the exhaust oxidizing gas supplied from the chamber 215 to the oxidizing gas discharge chamber 223 can be effectively lowered.

  The plurality of center-side cells 7 have a shorter upper core 1 disposed inside the base tube 103 than the plurality of end-side cells 6, so that the upper lead portion 8 has a plurality of end-side cells 6. Shorter than the upper lead portion 8. The plurality of center-side cells 7 have a shorter upper lead portion 8, so that the reforming reaction amount in the upper lead portion 8 is suppressed than the reforming reaction amount in the upper lead portion 8 of the plurality of end portion side cells 6. . By suppressing the amount of reforming reaction in the upper lead portion 8, the plurality of center side cells 7 have the reformed region 11 on the downstream side of the upper lead portion 8 being the reformed region 11 of the plurality of end side cells 6. Further, it extends to the inside of the power generation chamber 215. The vertical central portions of the plurality of center side cells 7 are formed by extending the reformed regions 11 of the plurality of center side cells 7 from the modified regions 11 of the plurality of end side cells 6 to the inside of the power generation chamber 215. Compared with the central part in the vertical direction of the plurality of end side cells 6, it is possible to effectively suppress the temperature of the region showing the maximum temperature by the heat absorption by the reforming reaction in the reforming region 11. For this reason, the vertical direction center part of the some center side cell 7 suppresses a temperature rise more compared with the perpendicular direction center part of the some edge part side cell 6. FIG.

  The plurality of cells 101 reduces the variation in temperature distribution of the plurality of cells 101 by suppressing the temperature rise in the central portion in the vertical direction of the power generation chamber 215 of the plurality of center-side cells 7 exhibiting the highest temperature. The temperature of 101 can be made uniform. Thus, by making the temperature of the fuel cell module 201 uniform, the reliability of the SOFC module device can be improved.

[Second Embodiment]
In the fuel cell module of the second embodiment, as shown in FIG. 7, the upper core inserted into the base tube 103 of the plurality of center side cells 7 is inserted into the base tube 103 of the plurality of end side cells 6. It is formed so that an outer diameter becomes smaller than the upper side core to be formed. The plurality of upper-side cores have the length of the upper-side core inserted into the base tube 103 of the plurality of center-side cells 7 such that the length of the upper-side core inserted into the base tube 103 of the plurality of end-side cells 6 It is formed to be equal to the length of.

  The plurality of center-side cells 7 are configured such that the outer diameter of the upper-side core 1 disposed inside the base tube 103 is smaller than the plurality of end-side cells 6, thereby transmitting the fuel gas formed in the upper lead portion 8. The heat area is smaller than the heat transfer area of the fuel gas formed in the upper lead portions 8 of the plurality of end side cells 6. The plurality of center side cells 7 have a small heat transfer area of the fuel gas formed in the upper lead portion 8, so that the reforming reaction amount in the upper lead portion 8 is the upper lead portion 8 of the plurality of end side cells 6. The amount of the reforming reaction is suppressed. The plurality of center-side cells 7 have the reforming reaction amount at the upper lead portion 8 suppressed, so that the reforming region 11 is extended to the inside of the power generation chamber. Effectively suppresses the temperature rise from the central part in the vertical direction of the plurality of end side cells 6.

  The plurality of cells 101 can improve the reliability of the SOFC module device by making the temperature of the fuel cell module 201 uniform by suppressing the temperature rise of the central cell 7 that is the highest temperature.

  The plurality of upper side cores have a plurality of reforming reaction amounts of the fuel gas without changing only one of the length or the outer diameter between the plurality of end side cells 6 and the plurality of center side cells 7. The end cell 6 and the plurality of center cells 7 may be different. For example, in the plurality of upper side cores, in the plurality of end side cells 6 and the plurality of center side cells 7, fuel reforming is promoted in the end side cells and fuel reforming is delayed in the center side cells. Both the length and the outer diameter of the upper core may be different. As a result, it is possible to improve the reliability of the SOFC module device by making the temperature inside the fuel cell module uniform by suppressing the temperature rise of the central cell 7 that is the highest temperature.

  Moreover, the upper side core 1 is good also as another material different from a metal. The material is exemplified by ceramic. For example, when the upper core 1 is made of ceramic, the thermal conductivity of the material is lowered, and as a result, the heat dissipation of the fuel cell module can be suppressed and the system efficiency of the entire SOFC can be improved.

  The upper core 1 of the end side cell may be provided with fins on the outer peripheral surface of the cylindrical portion 2. Examples of the fin include a plurality of protrusions and a groove formed in a spiral shape. By providing fins on the outer peripheral surface of the cylindrical portion 2 of the upper core 1 of the end cell, the reforming reaction of the fuel is promoted, the temperature of the end cell of the fuel cell module is increased, and the inside of the fuel cell module By making the temperature uniform, the reliability of the SOFC module device can be improved.

  A catalyst for reforming reaction may be applied to the outer peripheral surface of the cylindrical portion 2 on the upper core 1 of the end cell. An example of the catalyst is metallic nickel. By applying a catalyst to the outer peripheral portion of the upper core 1 of the end cell 101, the reforming reaction of the fuel is promoted, the temperature of the end cell of the fuel cell module is increased, and the temperature inside the fuel cell module is increased. By making it uniform, the reliability of the SOFC module device can be improved.

  In the above embodiment, the lower core is not described. However, in order to promote heat exchange between the exhaust fuel gas and the oxidizing gas, it is desirable to reduce the representative diameter as in the upper side. As a result, the reliability of the SOFC module device can be improved by increasing the temperature of the oxidizing gas supplied to the power generation chamber and making the temperature inside the fuel cell module uniform.

1: Upper side core (core)
2: cylinder portion 3: lid portion 5: plural claws 6: plural end side cells 7: plural central side cells 8: upper lead portion 11: reformed region 101: plural cells 103: base tube 201: fuel Battery module 215: power generation room

Claims (5)

A plurality of cells each having a plurality of flow paths through which fuel gas flows;
A plurality of cores respectively disposed in regions upstream of the plurality of flow paths,
The plurality of cells are:
A plurality of end-side cells;
Including a plurality of center side cells arranged to be surrounded by the plurality of end side cells,
The reforming of the fuel gas in the region in which the cores of the plurality of center side cells are arranged as compared with the reforming reaction amount of the fuel gas in the region in which the cores of the end side cells are arranged. A fuel cell module in which the plurality of cores are configured so that a reaction amount becomes small.   2. The fuel cell module according to claim 1, wherein the cores of the plurality of center side cells are shorter in the longitudinal direction of the flow path than the cores of the plurality of end side cells.   3. The fuel cell module according to claim 1, wherein an outer diameter of the cores of the plurality of center side cells is smaller than an outer diameter of the cores of the plurality of end side cells.   The fuel cell module according to claim 3, wherein the cores of the plurality of end side cells are provided with a plurality of fins on an outer peripheral surface facing an inner peripheral surface of the plurality of cells.   The fuel according to any one of claims 1 to 4, wherein in the plurality of cores, a catalyst for the reforming reaction is disposed on an outer peripheral surface facing an inner peripheral surface of the plurality of cells. Battery module.

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