JPWO2019003989A1 - Cell stack device, fuel cell module and fuel cell device - Google Patents

Abstract

The cell stack device of the present disclosure includes a cell stack including a plurality of fuel cells arranged along a predetermined arrangement direction, and an end conductor disposed at both ends of the cell arrangement and electrically connected to the cells. Member, a first conductive portion connected to the end conductive member and extending in a first direction away from the cell stack, and a through hole through which the first conductive portion passes, and the outer shape separates from the cell stack from the cell stack side And a bus bar having an insulating portion tapered toward the end side.

Description

  The present invention relates to a cell stack device, a fuel cell module and a fuel cell device.

  In recent years, as a next-generation energy, a fuel cell module formed by storing a cell stack device in which a plurality of fuel cells (SOFCs), which are a type of cell, are arranged in a storage container, and the fuel cell module Various fuel cell devices which are stored in the U.S. Pat.

  Also, in recent years, a high temperature steam electrolysis method using an electrolysis cell (SOEC) equipped with a solid oxide electrolyte membrane has been proposed as a type of cell.

Japanese Patent Application Publication No. 2007-59377

The cell stack device of the present disclosure is
A cell stack comprising a plurality of cells arranged along a predetermined arrangement direction;
End conductive members disposed at both ends in the arrangement direction of the cells and electrically connected to the cells;
A first conductive portion connected to the end conductive member and extending in a first direction away from the cell stack;
A bus bar having a through hole through which the first conductive portion penetrates, and an insulating portion whose outer shape is tapered from the cell stack side toward the side away from the cell stack;
Equipped with

  Moreover, the fuel cell module of this indication is provided with the above-mentioned cell stack apparatus, and the storage container which accommodates this cell stack apparatus.

  Furthermore, a fuel cell device according to the present disclosure includes the above-described fuel cell module, an accessory for operating the fuel cell module, and an outer case accommodating the fuel cell device module and the accessory.

The objects, features and advantages of the present disclosure will become more apparent from the following detailed description and the drawings.
It is a side view showing composition of a cell stack device of an embodiment. It is a perspective view showing the bus bar of the cell stack device of an embodiment. It is a side view of the above-mentioned bus bar. It is a sectional view of the above-mentioned bus bar. It is a perspective view showing the composition of the 2nd electric conduction part of the above-mentioned bus bar. It is a perspective view showing the composition of the 1st electric conduction part of the above-mentioned bus bar. It is a perspective view which shows the structure of the insulation part of the said bus-bar. It is a side view showing composition of a fuel cell module of an embodiment. It is a perspective view showing composition of a fuel cell device of an embodiment.

  FIG. 1 is a side view showing the configuration of the cell stack device of the embodiment. FIG. 2 is a perspective view showing the configuration of a part (bus bar) of the cell stack device of the embodiment, FIG. 3 is a side view of the bus bar of the embodiment, and FIG. 4 is a cross sectional view of the bus bar of the embodiment. 5A is a perspective view of a second conductive portion of the bus bar, FIG. 5B is a perspective view of a first conductive portion of the bus bar, and FIG. 5C is a perspective view of an insulating portion of the bus bar. In the present specification, for convenience, the orthogonal coordinate system (X, Y, Z) is defined, and the word such as upper or lower is used with the positive side in the Z-axis direction as the upper side.

  In the following figures, the explanation is mainly made using a solid oxide fuel cell, but the electrolysis cell produces hydrogen and oxygen by applying steam and voltage to the electrolysis cell to electrolyze steam. Can also be applied.

  The cell stack device 1 of the embodiment includes the cell stack 2, the end conductive member 4, and the bus bar 5.

  As shown in FIG. 1, the cell stack device 1 includes a cell stack 2 in which a plurality of cells 3 are arranged along a predetermined arrangement direction (X-axis direction). Adjacent cells 3 are electrically connected in series via conductive members 32. The lower end of the cell 3 is fixed to the manifold 20 by the insulating adhesive 33. Further, the end conductive member 4 is connected to the outermost cell 3 in the arrangement direction (X-axis direction) via the conductive member.

  The end conductive members 4 are disposed at both ends of the cell stack 2 in the arrangement direction of the cells 3 (X-axis direction), as shown in FIG. 1. The end conductive member 4 is electrically connected to the cell 3, and the current generated by the cell 3 is taken out via the end conductive member 4 or a voltage for electrolyzing water vapor in the cell 3 is obtained. It can be granted.

  The bus bar 5 is connected to the terminal 4 a of the end conductive member 4. The bus bar 5 has a first conductive portion 6 and an insulating portion 7 as shown in FIG. The bus bar 5 electrically connects the cell stack 2 stored in the storage container and the power conversion device or the power supply device (not shown) outside the storage container.

  The first conductive portion 6 has conductivity and extends in a first direction (X-axis positive direction) away from the cell stack 2. The first conductive portion 6 is electrically connected to the end conductive member 4. As shown in FIGS. 1 to 3, the first conductive portion 6 has a substantially rectangular plate-like base 8 extending in a straight line in the first direction.

  At one end of the base 8 on the cell stack 2 side, a protrusion 9 is provided which protrudes in the direction intersecting the first direction. The projecting portion 9 has a first projecting portion 9a connected to the base portion 8 and a second projecting portion 9b bent and substantially perpendicular to the first projecting portion 9a. The second protrusion 9 b is flat and has a hole 9 c penetrating in the thickness direction (see FIG. 5B). The second projection 9 b may be provided directly on the base 8 without providing the first projection 9 a.

  The insulating portion 7 is made of an insulating material having an insulating property, and extends in the first direction. The insulating portion 7 has a through hole 10 through which the first conductive portion 6 passes. The through hole 10 penetrates the insulating portion 7 in the first direction. The base 8 of the first conductive portion 6 is inserted into the through hole 10. One end of the base 8 on the cell stack 2 side and the other end on the side away from the cell stack 2 are exposed from the insulating portion 7. As a result, the state of electrical connection between the first conductive portion 6 and the end portion conductive member 4 and the state of connection between the first conductive portion 6 and the power conversion device or the power supply device outside the storage container can be visually confirmed. .

  The insulating portion 7 is attached via a flange to a hole penetrating the wall of the storage container, as described later, and extends in and out of the storage container. Thereby, the internal space of the storage container is airtightly sealed, and the first conductive portion 6 and the storage container are electrically insulated.

  The outer shape of the insulating portion 7 is tapered from the cell stack 2 side to the side away from the cell stack 2 as shown in FIGS. 2 and 5C. That is, the insulating portion 7 has a shape in which the outer shape narrows from the inside of the storage container to the outside of the storage container. As a result, it is possible to suppress the heat buildup of the end of the insulating portion 7 located outside the storage container (the end away from the cell stack 2), so the temperature inside the storage container is maintained at a high temperature. As a result, the operating efficiency of the cell stack device 1 can be improved.

  In the embodiment, as shown in FIG. 2, the outer shape of the insulating portion 7 when viewed in the extending direction (X-axis direction) of the insulating portion 7 is substantially circular on the cell stack 2 side and is separated from the cell stack 2 The insulating portion 7 has a tapered shape by being substantially oval on the side. The insulating portion 7 only needs to be thinner as it separates from the cell stack 2, and the outer shape of the insulating portion 7 on the cell stack 2 side and the outer shape on the side away from the cell stack 2 are oval, elliptical, rectangular It may be a shape or the like, or may be another shape. As an insulating material which comprises insulating part 7, a ceramic material, a glass material, etc. can be used, for example.

  As shown in FIG. 4, the through hole 10 has a narrow portion 10a on the side away from the cell stack 2 and a wide portion 10b on the cell stack 2 side, and the width of the wide portion 10b in the vertical direction is , And the width of the narrow portion 10a in the vertical direction. Thereby, when the base 8 of the first conductive portion 6 is inserted into the through hole 10 from the wide portion 10 b side at the time of manufacturing the cell stack device 1, the operation of inserting the base 8 into the through hole 10 becomes easy.

  The wide portion 10 b is filled with a filler 11 surrounding the first conductive portion 6. Thereby, the gap between the inner surface of the through hole 10 and the first conductive portion 6 in the wide portion 10 b can be closed. As a result, the airtightness of the storage container can be improved, and the insulating portion 7 can be prevented from dropping off from the first conductive portion 6. As the filler 11, for example, an insulating adhesive such as a glass sealing material can be used. In addition, the filler 11 may be filled also in the narrow part 10a.

  As illustrated in FIG. 4, the insulating unit 7 includes a restricting unit 12 that restricts the movement of the first conductive unit 6 in the first direction (X-axis positive direction). In the embodiment, as shown in FIG. 4, at the boundary between the wide portion 10 b and the narrow portion 10 a, a portion in which the width in the vertical direction of the through hole 10 is reduced is provided. . Further, the first conductive portion 6 has a pair of protrusions 6 a protruding in the width direction, and the pair of protrusions 6 a is configured to be able to abut on the regulating portion 12. According to such a configuration, the insertion position of the first conductive portion 6 with respect to the insulating portion 7 by bringing the pair of projections 6 a of the first conductive portion 6 into contact with the restricting portion 12 at the time of manufacturing the cell stack device 1; The insertion depth can be accurately and easily positioned.

  By the way, since the cells 3 operate at high temperature, thermal expansion and contraction (hereinafter collectively referred to as thermal deformation) are easily generated in the wall portion of the storage container, the cell stack 2 and the like. In particular, when the cell 3 is a fuel cell that performs power generation using a fuel gas and an oxygen-containing gas, the temperature in the storage container is about 500 to 800 ° C. during power generation, so the height direction of the cell stack 2 Thermal deformation may occur in all directions (the Z-axis direction), the arrangement direction of the cells 3 (X-axis direction), and the width direction (Y-axis direction) of the cells 3. Such thermal deformation may adversely affect the sealability and the like at the attachment portion between the storage container and the bus bar 5 and may reduce the operation efficiency of the cell stack device 1. In order to suppress the decrease in the operating efficiency of the cell stack device 1, the bus bar 5 may be provided with a configuration capable of absorbing thermal deformation.

  As a configuration of the bus bar 5 capable of absorbing thermal deformation, there is a configuration in which the first conductive portion 6 and the end portion conductive member 4 are connected using a wire excellent in flexibility and heat resistance. Wires having the properties are expensive, and the cost of the cell stack device 1 is increased. Although there is also a configuration in which the first conductive portion 6 and the end portion conductive member 4 are connected using a thin conductive member or a thin conductive member, such a configuration increases the electrical resistance of the bus bar 5. This results in power loss, which in turn reduces the operating efficiency of the cell stack device 1. Alternatively, although it is conceivable to make the bus bar 5 mechanically strong to suppress the deformation of the bus bar 5, the mechanically strong bus bar 5 applies a thermal stress to the root of the cell stack 2 to make the cell stack 2 There is a risk of damaging the

  In the embodiment, in order to make the bus bar 5 have a configuration capable of absorbing thermal deformation, for example, as shown in FIG. 2, the first conductive portion 6 and the end conductive member 4 are bent in a strip material having conductivity. Electrically and mechanically connected through the second conductive portion 13.

  The second conductive portion 13 is connected to the first portion 14 electrically and mechanically connected to the terminal portion 4 a of the end conductive member 4 and the first portion 14, and electrically and mechanically connected to the first conductive portion 6. And a second portion 15 connected to the

  The first portion 14 includes a first connection portion 14 a, a first straight portion 14 b, a second straight portion 14 c, and a first bent portion 14 d.

  The first connection portion 14 a is flat and has a hole 14 e penetrating in the thickness direction. Although not shown, the first connection portion 14a and the end conductive member 4 may be, for example, a bolt passing through the hole 14e of the first connection portion 14a and the hole 4b of the end conductive member 4 and a nut screwed on the bolt And can be fixed.

  The first straight portion 14b is continuous with the first connection portion 14a and extends in a straight line. For example, as shown in FIG. 5A, the first straight portion 14b extends in the height direction (Z-axis direction) of the cell stack 2 and extends in the direction (X-axis positive direction) away from the cell stack 2. The second straight portion 14 c extends in a straight line in the height direction (Z-axis direction) of the cell stack 2. The lower end of the second straight portion 14c is located below the first connection portion 14a. The first bent portion 14 d connects one end of the first straight portion 14 b and one end of the second straight portion 14 c. In the embodiment, as shown in FIG. 2, the first bent portion 14 d is bent when viewed in the width direction (Y-axis direction) of the cell 3, but the first bent portion 14 d is a first straight line. It may extend substantially in a straight line between one end of the portion 14b and one end of the second straight portion 14c.

  As shown in FIGS. 3 and 5A, the first portion 14 of the second conductive portion 13 is bent in a concave shape that opens downward, that is, in a reverse concave shape. Thereby, each free end can be easily bent and deformed in the direction in which each free end approaches or separates from the proximal end closer to the first bending portion 14d of the first linear portion 14b and the second linear portion 14c. Therefore, thermal deformation in the height direction (Z-axis direction) of the cell stack 2 and the arrangement direction (X-axis direction) of the cells 3 can be absorbed.

  The second portion 15 of the second conductive portion 13 has a second connection portion 15a, a third straight portion 15b, and a second bent portion 15c.

  The second connection portion 15a is flat and has a hole 15d penetrating in the thickness direction. Although not shown, the second connection portion 15a and the first conductive portion 6 may be, for example, a bolt passing through the hole 15d of the second connection portion 15a and the hole 9c of the first conductive portion 6, and a nut screwed on the bolt And can be fixed.

  The third straight portion 15b is bent at approximately a right angle to the second connection portion 15a and extends in a straight line in the height direction of the cell stack 2 (Z-axis direction). The third linear portion 15 b is spaced apart from the first linear portion 14 b and the second linear portion 14 c in the width direction (Y-axis direction) of the cell 3. Further, the third straight portion 15 b is provided such that the normal direction of the first surface (one main surface) 15 e is orthogonal to the arrangement direction of the cells 3 (X-axis direction). For example, as shown in FIGS. 2 and 5A, the second bending portion 15c extends in the arrangement direction (X-axis direction) of the cells 3 and the width direction (Y-axis direction) of the cells 3, and The lower end of the third straight portion 15b is connected, and the third straight portion 15b is bent in a direction different from the first bent portion 14d.

  According to the second portion 15 of the above configuration, the third straight portion 15 b has the free end portion connected to the second connection portion 15 a with respect to the base end portion near the second bending portion 15 c in the width direction of the cell 3 ( It can be easily deformed in the Y-axis direction). Thereby, the second portion 15 can absorb thermal deformation in the width direction (Y-axis direction) of the cell 3. Further, in the width direction (Y-axis direction) of the cell 3, the third straight portion 15 b is in the width direction of the cell 3 because the third straight portion 15 b is separated from the first straight portion 14 b and the second straight portion 14 c. A collision between the first conductive portion 6 and the second conductive portion 13 when deformed in the (Y-axis direction) can be suppressed.

  The bus bar 5 includes a first bent portion 14d bent in a width direction (Y-axis direction) of the cell 3 and a second bent portion 15c bent in a height direction (Z-axis direction) of the cell stack 2. Have. Thus, the bus bar 5 has a plurality of bent portions that bend in directions orthogonal to each other, whereby the height direction of the cell stack 2 (Z-axis direction), the arrangement direction of the cells 3 (X-axis direction), and the cells 3 It is possible to absorb thermal deformation in all directions in the width direction (Y-axis direction) of

  The first conductive portion 6 and the second conductive portion 13 may be configured such that the thickness of the first conductive portion 6 is larger than the thickness of the second conductive portion 13. By making the thickness of the first conductive portion 6 larger than the thickness of the second conductive portion 13, the electrical resistance of the first conductive portion 6 is reduced, and the bus bar 5 and an external power converter or power supply device etc. It is possible to suppress the power loss between itself and the other (not shown). Further, by making the thickness of the second conductive portion 13 smaller than the thickness of the first conductive portion 6, the bending rigidity of the second conductive portion 13 can be reduced, and the second conductive portion can easily follow thermal deformation. It can be 13. The thickness of the first conductive portion 6 is, for example, 1 to 4 mm, and the thickness of the second conductive portion 13 is, for example, 0.5 to 2 mm.

  As described above, the bus bar 5 is configured such that the first conductive portion 6 extending substantially in a straight line and the second conductive portion 13 having the bent portion can be separated. According to such a configuration, after the space between the first conductive portion 6 and the inner surface of the through hole 10 of the insulating portion 7 is filled with the filler 11, the first conductive portion 6 and the insulating portion 7 are manufactured. The assembly of the part 7 and the second conductive part 13 can be connected, which can improve the workability.

  The bus bar 5 configured as described above is effective in thermal deformation in all directions of the height direction (Z axis direction) of the cell stack 2, the arrangement direction (X axis direction) of the cells 3 and the width direction (Y axis direction) of the cells 3. Can be absorbed. Therefore, according to the cell stack device 1 of the embodiment, the thermal deformation by the bus bar 5 can be suppressed to improve the operation efficiency. Further, according to the cell stack device 1 of the embodiment, thermal deformation generated during operation is absorbed by the bus bar 5 to suppress breakage of the cell stack 2 and deterioration of sealing performance at the attachment portion between the storage container and the bus bar 5. Thus, it is possible to provide the cell stack device 1 excellent in reliability and durability.

  FIG. 6 is a side view showing the configuration of a fuel cell module 16 of an embodiment in which the above-described cell stack device 1 is stored in a storage container. The fuel cell module 16 according to the embodiment includes a cell stack device 1 in which a plurality of fuel cells 3 which is a type of cell 3 are arranged. A reformer 17 for generating fuel gas to be supplied to the cells 3 is disposed above the cell stack device 1.

  The reformer 17 reforms the raw fuel such as natural gas and kerosene supplied via the raw fuel supply pipe 18 to generate a fuel gas. The fuel gas generated by the reformer 17 is supplied to the manifold 20 via the gas flow pipe 19, and is supplied to the fuel cell 3 from the manifold 20.

  In the bus bar 5 of the cell stack device 1, the second conductive portion 13 is connected to the terminal portion 4 a of the end conductive member 4, and the insulating portion 7 is attached to the wall of the storage container 23 via the flange 22.

  Here, in the conventional cell stack device, the temperature in the storage container decreases due to the heat of the insulating portion (insulator) surrounding the conductive portion of the bus bar extending in and out of the storage container, and the operation efficiency of the cell stack device decreases. There was a case.

  On the other hand, according to the fuel cell module 16 of the embodiment having the above configuration, heat generation by the bus bar 5 can be suppressed, and power generation efficiency can be improved. Further, according to the fuel cell module 16 of the embodiment, since the thermal deformation occurring in the wall of the storage container 23, the cell stack 2, the end conductive member 4 and the like can be absorbed by the bus bar 5, reliability and durability The fuel cell module 16 is excellent.

  FIG. 7 is a perspective view schematically showing the configuration of a fuel cell device 24 according to an embodiment formed by housing the above-described fuel cell module 16 and accessories for operating the fuel cell module in an outer case. FIG. In FIG. 7, the configuration is partially omitted.

  The fuel cell device 24 shown in FIG. 7 divides the inside of the outer case composed of the support column 25 and the exterior plate 26 into upper and lower portions by a partition plate 27, and the upper side thereof is a module storage chamber 28 for storing the fuel cell module 16. The lower side is configured as an accessory storage chamber 29 for storing accessories for operating the fuel cell module 16. In FIG. 7, auxiliary devices stored in the auxiliary device storage room 29 are not shown.

  Further, the partition plate 27 is provided with an air circulation port 30 for flowing the air of the accessory storage chamber 29 to the module storage chamber 28 side, and a part of the exterior plate 26 constituting the module storage chamber 28 An exhaust port 31 for exhausting the air in the module storage chamber 28 is provided.

  The fuel cell device 24 of the embodiment can be a fuel cell device 24 with improved power generation efficiency by housing the fuel cell module 16 including the cell stack device 1 as described above in the outer case.

  As mentioned above, although this indication was explained in detail, this indication is not limited to the above-mentioned embodiment, In the range which does not deviate from the gist of this indication, various change, improvement, etc. are possible.

  Furthermore, the present disclosure can be implemented in other various forms without departing from the spirit or main features thereof. Accordingly, the above-described embodiments are merely illustrative in every respect, and the scope of the present disclosure is as set forth in the claims, and is not limited in any way by the description. Furthermore, all variations and modifications that fall within the scope of the claims fall within the scope of the present disclosure.

1 cell stack device 2 cell stack 3 cell (fuel cell)
4 end conductive member 5 bus bar 6 first conductive portion 7 insulating portion 8 base portion 9 projecting portion 10 through hole 11 filler 12 restricting portion 13 second conductive portion 14 first portion 15 second portion 16 fuel cell module 23 storage container 24 Fuel cell device

The cell stack device of the present disclosure, end the cell stack comprising a plurality of cells arranged along the array direction to define pre Me, disposed in the array direction of the ends of the front SL cells, are the cells electrically connected and Bushirubeden member, is connected to the front Kitan portion conductive member includes a first conductive portion extending in a first direction away from the cell stack, the previous SL through hole first conductive portion extends, the outer shape is the And a bus bar having an insulating portion tapered from the cell stack side to the side away from the cell stack. The through hole has a narrow portion on the side away from the cell stack and a wide portion on the cell stack side.

Claims (10)

A cell stack comprising a plurality of cells arranged along a predetermined arrangement direction;
End conductive members disposed at both ends in the arrangement direction of the cells and electrically connected to the cells;
A first conductive portion connected to the end conductive member and extending in a first direction away from the cell stack;
A bus bar having a through hole through which the first conductive portion penetrates, and an insulating portion whose outer shape is tapered from the cell stack side toward the side away from the cell stack;
Cell stack apparatus comprising:   The cell stack device according to claim 1, wherein the through hole has a narrow portion on the side away from the cell stack and a wide portion on the cell stack side.   The cell stack device according to claim 2, wherein a filling material surrounding at least the first conductive portion is included in at least the wide portion. The insulating portion has a restricting portion that restricts the movement of the first conductive portion in the first direction,
The cell stack device according to any one of claims 1 to 3, wherein the first conductive portion has a pair of protrusions that can be in contact with the restriction portion and project in the width direction. The bus bar further includes a second conductive portion formed by bending a conductive strip material;
The second conductive portion is disposed between the first conductive portion and the end conductive member to electrically connect the first conductive portion and the end conductive member. The cell stack device according to any one.   The cell stack device according to claim 5, wherein a thickness of the first conductive portion is larger than a thickness of the second conductive portion.   The cell stack device according to claim 5, wherein the second conductive portion has a plurality of bending portions that bend in different directions.   The cell stack device according to claim 7, wherein bending directions of the plurality of bending parts are directions orthogonal to each other.   A fuel cell module comprising the cell stack device according to any one of claims 1 to 8 and a storage container for storing the cell stack device.   A fuel cell device comprising: the fuel cell module according to claim 9; an accessory for operating the fuel cell module; and an outer case accommodating the fuel cell device module and the accessory.

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