JP2023010793A - Electrochemical cell stack, fuel cell and hydrogen production apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electrochemical cell stack, a fuel cell, and an electrolysis apparatus capable of reducing unevenness of fuel gas and air to be supplied to each cell without changing an installation area.

SOLUTION: An embodiment of the present invention includes a laminate in which cells and separators are alternately laminated, and the side surfaces of the cells are surrounded by the separators, a manifold which is disposed on an end surface of the laminate and has a fuel introduction portion for introducing fuel gas from the outside and an air introduction portion for introducing air from the outside, a fuel supply flow path which is a flow path of fuel gas to be supplied to the cells, penetrates the separators from the fuel introduction portion and extends in a lamination direction thereof, and an air supply flow path which is a flow path of air to be supplied to the cells, penetrates the separators from the air introduction portion and extends in the lamination direction thereof. The cells form a plurality of cell groups in the lamination direction, and at least one of the fuel supply flow path and the air supply flow path is provided for each cell group.

SELECTED DRAWING: Figure 2

COPYRIGHT: (C)2023,JPO&INPIT

Description

Embodiments of the present invention relate to electrochemical cell stacks, fuel cells and hydrogen production devices.

An electrochemical cell (hereinafter referred to as a cell), which is the minimum structural unit of a planar solid oxide fuel cell (SOFC) and a solid oxide electrolysis cell (SOEC), comprises a fuel electrode, an electrolyte, and an air electrode. It is formed by sequentially laminating. When this cell is mounted on an SOFC, a fuel gas (hydrogen or carbon monoxide) is externally supplied to the fuel electrode and air is externally supplied to the air electrode, thereby causing an electrochemical reaction in the cell. As a result, electrical energy is produced in the cell. On the other hand, when this cell is mounted on an SOEC, fuel gas (water vapor) is supplied to the fuel electrode from the outside, and electric energy is supplied to the cell from the outside, and the water vapor is electrolyzed into oxygen and hydrogen in the cell. do.

A flat plate electrochemical cell stack (hereafter referred to as a cell stack) is a laminate in which cells and separators are alternately stacked. be done. The manifolds are arranged, for example, on the upper and lower end surfaces of the cell stack in the stacking direction and on the side surfaces of the cell stack. The separator is provided with a fuel supply hole and an air supply hole penetrating in the stacking direction, a horizontal fuel supply hole connected to the fuel supply hole, and a horizontal air supply hole connected to the air supply hole. The fuel supply hole and the air supply hole each form a channel extending in the stacking direction of the stack. The horizontal fuel supply hole connects the fuel supply hole and the fuel electrode of each cell, and together with the fuel supply hole constitutes a fuel gas flow path. The horizontal air supply hole connects the air supply hole and the air electrode of each cell, and constitutes an air flow path together with the air supply hole.

That is, the fuel gas introduced into the manifold from the outside is supplied to the fuel electrode through the fuel supply hole and the fuel supply horizontal hole in that order. Further, when the cell stack is mounted on the SOFC, the air introduced from the outside into the manifold is supplied to the air electrode through the air supply hole and the air supply horizontal hole in order.

JP 2016-81813 A

By the way, in order to increase the amount of electric energy generated in an SOFC and the amount of oxygen and hydrogen generated in an SOEC (hereinafter collectively referred to as an increase in cell stack capacity), a plurality of cell stacks are integrated, or a single cell stack is used. It is necessary to increase the stacking number of cells stacked in a single cell stack. Among these, when a plurality of cell stacks are integrated, since the cell stacks are integrated in a direction orthogonal to the stacking direction, a large space is required for installation. Therefore, in order to realize a cell stack that has a large capacity and does not depend on installation space, it is required to increase the number of cells stacked inside one cell stack.

However, when the number of stacked cells in one cell stack increases, the amount of fuel gas or air supplied to the cells closer to the manifold increases, causing a bias in the stacking direction. If there is an imbalance in the amount of fuel gas or air supplied, there will be a difference in the amount of reaction in each cell, causing local thermal stress to occur in the cells with higher reaction amounts (cells on the side closer to the manifold), and the cell stack. May cause performance degradation.

Therefore, the problem to be solved by the present invention is to provide an electrochemical cell stack, a fuel cell, and a hydrogen production apparatus that can reduce the unevenness of fuel gas and air supplied to each cell without changing the installation area. .

In order to solve the above problems, an electrochemical cell stack of an embodiment includes a laminate in which cells and separators are alternately laminated, and the side surfaces of the cells are surrounded by the separators; A manifold provided with a fuel introduction portion for introducing fuel gas from the outside and an air introduction portion for introducing air from the outside, and a flow path for the fuel gas supplied to the cell, wherein the fuel introduction portion a fuel supply channel extending from the separator through the separator and extending in the stacking direction; and an air channel for supplying air to the cells, the air supply channel extending from the air introduction portion through the separator and extending in the stacking direction. and a channel, wherein the cells form a plurality of cell groups in the stacking direction, and at least one of the fuel supply channel and the air supply channel is provided for each cell group.

According to the present invention, it is possible to reduce the unevenness of fuel gas and air supplied to each cell without changing the installation area.

1 is a diagram showing the configuration of a cell stack according to the first embodiment; FIG. It is the figure which expanded a part of FIG. FIG. 2 is a sectional view of FIG. 1, showing (a) a PP sectional view and (b) a QQ sectional view, respectively; FIG. 5 is a diagram showing the configuration of a cell stack according to a modification of the first embodiment; FIG. FIG. 10 is a diagram showing the configuration of a cell stack according to another modification of the first embodiment; FIG. 5 is a diagram showing the configuration of a cell stack according to a second embodiment; FIG. FIG. 10 is a diagram showing a configuration of a cell stack according to a modification of the second embodiment; FIG. FIG. 10 is a diagram showing the configuration of a cell stack according to another modification of the second embodiment;

(First embodiment)
An electrochemical cell stack according to the first embodiment will be described with reference to FIGS. 1 to 3. FIG. FIG. 1 is a schematic diagram showing the configuration of a cell stack according to the first embodiment, and FIG. 2 is an enlarged view of a part of FIG. 3 is a sectional view of FIG. 1, showing (a) a PP sectional view and (b) a QQ sectional view, respectively. In the following description, an electrochemical cell is described as a cell, and an electrochemical cell stack is described as a cell stack.

As shown in FIGS. 1 and 3, the cell stack 1 includes a stack 10, a manifold 20, a fuel supply channel 30, an air supply channel 35, a fuel discharge channel 40, and an air discharge channel 45. and In the following description, the direction in which cells 11 and separators 12 are stacked (to be described later) will be referred to as the stacking direction (z direction), and the stacking direction will be used as a reference when describing the direction or a specific surface. For example, the upper surface refers to the upper surface based on the stacking direction, the side surface refers to the side surface based on the stacking direction, and the lower side refers to the lower side based on the stacking direction. Note that the stacking direction here does not necessarily match the direction of gravity.

As shown in FIG. 2 , the laminate 10 includes cells 11 , separators 12 , sealing plates 13 and sealing materials 14 . The laminate 10 referred to here refers to the entire laminate obtained by laminating a plurality of such units, with the separator 12 having the cells 11 arranged thereon, the sealing plate 13, and the sealing material 14 sequentially laminated as one unit.

The cell 11 is a flat plate cell in which a fuel electrode 11a, an electrolyte 11b, and an air electrode 11c are sequentially stacked. The cell 11 supplies fuel gas to a fuel chamber 15 (described later) and air to an air chamber 16 (described later) to cause a chemical reaction. The term "chemical reaction" as used herein refers to a reaction that generates electrical energy (power generation reaction) when used as an SOFC, and an electrolysis reaction when used as an SOEC. The fuel gas indicates, for example, hydrogen or carbon monoxide when used in SOFC, and water vapor when used in SOEC.

The separator 12 is a plate-like member arranged so as to surround the side surface of the cell 11 and has electrical conductivity. In this embodiment, the separator 12 is arranged from the side surface of the cell 11 to surround the cell 11 with a predetermined gap therebetween. That is, the upper surface of the separator 12 is provided with a cell accommodating portion 12a recessed downward from this surface, and the cells 11 are arranged inside the cell accommodating portion 12a. However, to surround the side surface of the cell 11 is not limited to the case where the side surface of the cell 11 and the cell containing portion 12a of the separator 12 are separated by a predetermined gap. It may be adjacent to the inner peripheral surface of the portion 12a.

The sealing plate 13 is a conductive plate-like member and is provided on the upper surface of the separator 12 . More specifically, the sealing plate 13 has an opening at least in its center, and the separator 12 is arranged so that the upper surface of the cell 11 can be seen through this opening when viewed from the upper surface of the sealing plate 13 . Placed on top.

The sealing material 14 is a plate-like member having conductivity. A sealing material 14 is arranged on the upper surface of the sealing plate 13 .

In each unit constituting the laminate 10, a fuel chamber 15 is provided between the cell containing portion 12a and the sealing plate 13, and fuel gas is supplied to the fuel chamber 15. As shown in FIG. An air chamber 16 is provided between the opening of the sealing plate 13 , the sealing material 14 , and another unit of the separator 12 in contact with the sealing material 14 , and air is supplied to the air chamber 16 .

The manifold 20 is provided on the lower end surface of the laminate 10 and has a fuel introduction portion 20a for introducing fuel gas from the outside and an air introduction portion 20b (not shown) for introducing air. In this embodiment, the case where the fuel introduction portion 20a and the air introduction portion 20b are provided in the same manifold 20 will be described as an example. good.

The fuel supply passage 30 includes two fuel supply holes 31a and 31b extending along the stacking direction from the fuel introduction portion 20a, one of the fuel supply holes 31a and 31b, and a fuel chamber 15 provided in each unit. It is a passage on the fuel gas supply side provided with a fuel supply horizontal hole 32 to be connected.

Here, the fuel supply channel 30 will be described in more detail with reference to FIGS. 2 and 3. FIG. In the following description, the upper side and the lower side inside the laminate 10 relatively indicate the installation position of each unit. For example, when the electrochemical cell stack 1 is configured by stacking a total of 41 units, the 20 units counted from the top end in the stacking direction are the upper part of the inside of the laminate 10, and the remaining 21 units are the inside of the laminate 10. on the lower side.

As shown in FIG. 2 and FIG. 3( a ), in the lower part of the laminate 10 , the separators constituting each unit are placed from the outside of the side surface of the cell 11 (outside in the radial direction centering on the z-axis). 12, the sealing plate 13 and the sealing member 14 are provided with fuel supply holes 31a and 31b extending in the stacking direction through the edges thereof. The fuel supply holes 31a provided in the respective separators 12 are adjacent to each other in the stacking direction and constitute one channel extending in the stacking direction. Similarly to the fuel supply holes 31a, the fuel supply holes 31b provided in the respective separators 12 are adjacent to each other in the stacking direction and constitute one flow path extending in the stacking direction. These two flow paths are respectively provided on the lower side of the inside of the stack 10 , and the fuel supply hole 31 a is connected to the fuel supply horizontal hole 32 and is located on the lower side of the inside of the stack 10 . Flow paths for supplying fuel gas to the respective fuel chambers 15 are configured. The fuel supply hole 31 b is not connected to the lower fuel supply horizontal hole 32 inside the stack 10 .

On the other hand, as shown in FIGS. 2 and 3B, a fuel supply hole 31b extending from the lower side of the stack 10 is provided in the upper side of the stack 10 inside. That is, the fuel supply hole 31b provided in each separator 12 is connected to the lower fuel supply hole 31b inside the stack 10 to form a single flow path extending from the fuel introduction portion 20a in the stacking direction. do. The fuel supply hole 31 b is connected to the fuel supply horizontal hole 32 and constitutes a flow path for supplying fuel gas to each of the fuel chambers 15 located on the upper side of the stack 10 .

The cross-sectional areas of the fuel supply holes 31a and 31b in the cross section perpendicular to the stacking direction are designed so that the unevenness in the flow rate of the fuel gas flowing between the upper and lower sides of the stack 10 is reduced. there is The fact that the unevenness in the flow rate of the fuel gas is reduced here means that the fuel gas does not flow locally in a part of the stack 10, and includes the case where the flow rate inside the stack 10 becomes uniform. be

As shown in FIG. 3, the air supply channel 35 is provided in each unit with two air supply holes 36a and 36b extending along the stacking direction from the air introduction portion 20b and one of the air supply holes. It is an air supply side passage provided with an air supply horizontal hole 37 that connects with the air chamber 16 . The air supply channel 35 is arranged at a position not in contact with the fuel supply channel 30 when viewed from cross sections (PP cross section and QQ cross section) perpendicular to the stacking direction. Other structures of the air supply channel are the same as those of the fuel supply channel 30 .

The fuel discharge channel 40 is provided on the side of the separator 12 facing the fuel supply channel 30 with the cell containing portion 12a as a boundary. A fuel discharge lateral hole 42 is provided to connect the fuel chambers 15 provided in the unit. The fuel discharge hole 41 is connected to a fuel discharge port 43 provided in the manifold 20 separately from the fuel introduction portion 20a.

The air discharge channel 45 is provided on the side of the separator 12 facing the air supply channel 35 with the cell containing portion 12a as a boundary. It has an air discharge lateral hole 47 connecting the air chamber 16 provided therein. The air discharge hole 46 is connected to an air discharge port (not shown) provided separately from the air introduction portion 20b. Other structures of the air discharge channel are the same as those of the fuel discharge channel 40 .

Next, the operation of this embodiment will be described. In the following description, hydrogen is used as the fuel gas when the cell stack 1 is used as an SOFC, and water vapor is used as the fuel gas when the cell stack 1 is used as an SOEC.

(When operating as SOFC)
Hydrogen (fuel gas) introduced from the outside into the fuel introduction portion 20a of the manifold 20 is supplied to the fuel chamber 15 through the fuel supply hole 31a or 31b and the fuel supply horizontal hole 32 provided in each unit. . That is, hydrogen is supplied to the fuel chamber 15 from the fuel introduction portion 20a through the fuel supply hole 31a and the fuel supply horizontal hole 32 in the lower side of the stack 10, and the fuel is introduced into the upper side of the stack 10. Hydrogen is supplied from the portion 20a to the fuel chamber 15 through the fuel supply hole 31b and the fuel supply horizontal hole 32 in order. This hydrogen is used as a reactant in the power generation reaction (the reaction that produces electrical energy) in cell 11 . On the other hand, the hydrogen that has not been used for the power generation reaction in the cell 11 is discharged outside from the fuel discharge port 43 through the fuel discharge horizontal hole 42 and the fuel discharge hole 41 .

Air introduced into the air introduction portion 20b of the manifold 20 from the outside passes through either the air supply holes 36a and 36b in the same manner as hydrogen, and passes through the air supply horizontal holes 37 provided in each unit. chamber 16 is supplied. This air is used as a reactant in the power generation reaction in the cells 11 of each unit. On the other hand, the air that has not been used for the power generation reaction in the cell 11 passes through the horizontal air discharge hole 47 and the air discharge hole 46 and is discharged outside from an air discharge port (not shown).

(When operating as SOEC)
Water vapor (fuel gas) introduced from the outside into the fuel introduction portion 20a of the manifold 20 passes through the fuel supply hole 31a or 31b and the fuel supply horizontal hole 32 provided in each unit, and is supplied to the fuel chamber 15. . That is, steam is supplied to the fuel chamber 15 from the fuel introduction portion 20a through the fuel supply hole 31a and the fuel supply horizontal hole 32 in the lower part of the inside of the stack 10, and the fuel is introduced into the upper part of the inside of the stack 10. Steam is supplied to the fuel chamber 15 from the portion 20a through the fuel supply hole 31b and the fuel supply horizontal hole 32 in order. This water vapor is used as a reactant for the electrolysis reaction in cell 11 . On the other hand, the water vapor that has not been used for the electrolysis reaction in the cell 11 passes through the fuel discharge horizontal hole 42 and the fuel discharge hole 41 and is discharged from the fuel discharge port 43 to the outside.

That is, in the present embodiment, when the upper side and the lower side of the same laminate 10 are viewed as different cell groups, by providing a fuel supply hole and an air supply hole for each of these cell groups, the inside of the laminate 10 can be Fuel gas and air can be evenly supplied to the upper and lower sides of the .

According to the first embodiment described above, by providing a plurality of fuel supply holes and air supply holes respectively corresponding to the upper side and the lower side in the stacking direction, each cell 11 Fuel gas and air can be supplied evenly to the As a result, in the laminate 10, the reaction amount of each cell 11 in the lamination direction is not biased, and local thermal stress is less likely to occur. Therefore, even when the number of stacked cells 11 forming the stacked body 10 is increased, the performance is less likely to deteriorate. In addition, since the fuel supply holes 31a and 31b and the air supply holes 36a and 36b are provided by effectively utilizing the existing space, the cell stack 1 can be provided with new pipes outside the stack 10. It is no longer necessary to secure the installation space.

In this embodiment, the fuel supply channel 30 has two fuel supply holes 31a and 31b, and the air supply channel 35 has two air supply holes 36a and 36b. For example, a configuration may be adopted in which there are a plurality of either the fuel supply holes or the air supply holes. That is, a configuration having two fuel supply holes 31a and 31b and one air supply hole, or a configuration having one fuel supply hole and two air supply holes 36a and 36b may be used. Further, the number of fuel supply holes and air supply holes is not limited as long as they are provided in each cell group inside the same laminate 10 . For example, when three cell groups are configured inside the same laminate 10, three fuel supply holes and three air supply holes may be provided, and when four cell groups are configured, fuel supply holes and four air supply holes may be provided. Further, in combination with the modified example described above, only one of the fuel supply path and the air supply path may be provided in plural, and the other may be provided in a single configuration. This relationship regarding the number of flow paths also holds true in other embodiments described later.

In addition, in the present embodiment, the case where the manifold 20 is installed on the lower end surface of the laminate 10 has been described as an example, but this installation position may be arranged on the end surface of the laminate 10, for example, on the upper side. or the side surface of the laminate 10 .

Furthermore, in the present embodiment, the fuel supply holes 31a and 31b and the air supply holes 36a and 36b form flow paths extending in the stacking direction. is not limited to a line-segment flow path extending in the stacking direction. For example, as shown in FIG. 4, the fuel supply holes 31a and 31b may be bent halfway in the stacking direction. That is, the fuel supply channel 30 in the present embodiment only needs to have different channels for supplying fuel gas between the upper cell 11 and the lower cell 11 inside the laminate 10, and the fuel supply hole 31a is not necessarily required. and 31b do not have to extend only in the stacking direction. This relationship regarding the channel structure is the same for the air supply channel 35 in this embodiment.

Furthermore, in this embodiment, a side cross section of the laminate 10 (oriented in FIGS. 1, 2, and 4) is shown to show that there are a plurality of fuel supply holes 31a, 31b and air supply holes 36a, 36b. Therefore, the case where these supply holes do not overlap each other has been exemplified and explained. However, this arrangement position is not limited as long as the fuel supply channel 30 and the air supply channel 35 do not contact each other. For example, they are arranged as shown in FIG. They may overlap.

(Second embodiment)
An electrochemical cell stack according to the second embodiment will be described with reference to FIG. FIG. 6 is a schematic diagram showing the configuration of a cell stack according to the second embodiment. Hereinafter, portions different from the first embodiment will be described, and other portions will be the same as those in the first embodiment and given the same figure numbers, and the description thereof will be omitted.

As shown in FIG. 6, the cell stack 1 includes a stack 10, a manifold 50, a fuel supply channel 60, an air supply channel 65 (not shown), a fuel discharge channel 70, and an air discharge channel. A channel 75 (not shown) is provided. In the second embodiment, the fuel supply holes and the air supply holes are arranged differently from the first embodiment.

The manifold 50 is sandwiched between the stacks 10 and includes a fuel introduction portion 50a for introducing fuel gas from the outside and an air introduction portion 50b (not shown) for introducing air. That is, in one laminate 10, the cells 11 are provided respectively above and below the manifold 50 in the lamination direction. The fuel introduction portion 50a is connected to each of fuel supply holes 61a and 61b, which will be described later, and the air introduction portion is connected to each of two air supply holes, which will be described later.

The fuel supply channel 60 has fuel supply holes 61 a and 61 b and a fuel supply horizontal hole 62 . The fuel supply hole 61a is provided above the fuel introduction portion 50a of the manifold 50, and the fuel supply hole 61b is provided below the fuel introduction portion 50a of the manifold 50, respectively. The horizontal fuel supply hole 62 is connected to each unit of the fuel chamber 15 that constitutes each of the stacks 10 . That is, the horizontal fuel supply hole 62 above the fuel introduction portion 50a is connected to the fuel supply hole 61a, and the horizontal fuel supply hole 62 below the fuel introduction portion 50a is connected to the fuel supply hole 61b. The cross-sectional area of the fuel supply holes 61a and 61b in the cross section perpendicular to the stacking direction is designed so that the fuel gas is evenly supplied to the stacks 10, respectively. Other configurations are the same as those of the fuel supply channel 30 in the first embodiment.

The air supply channel 65 (not shown) has two air supply holes 66 a and 66 b and an air supply horizontal hole 67 . The air supply holes 66 a and 66 b are provided one above and one below the air introduction portion of the manifold 50 . The horizontal air supply hole 67 connects the air chamber 16 of each unit constituting the laminate 10 and any of the air supply holes. That is, the air supply horizontal hole 67 above the air introduction portion 50b is connected to the air supply hole 66a above the air introduction portion 50b, and the air supply horizontal hole 67 below the air introduction portion 50b is connected to the air supply hole 66b. It connects with the air supply hole 66b below the introduction part 50b. The channel cross-sectional area of each air supply hole in a cross section perpendicular to the stacking direction is designed so that air is evenly supplied to each of the upper and lower stacks 10 . Other configurations are the same as those of the air supply channel 35 in the first embodiment.

The fuel discharge passage 70 has a fuel discharge hole 71 a provided above the fuel introduction portion 50 a , a fuel discharge hole 71 b provided below the fuel introduction portion 50 a , and a fuel discharge horizontal hole 72 .

Air discharge passages 75 (not shown) are provided above and below the air introduction portion, respectively, and include air discharge holes 76 and air discharge horizontal holes 77 . Other configurations of the air discharge channel 75 are the same as those of the air discharge channel 45 in the first embodiment.

That is, in the present embodiment, when the cells above and below the manifold 50 are viewed as separate cell groups, these cell groups are provided with fuel supply holes and air supply holes, respectively. Fuel gas and air are evenly supplied to the cells 11 on each side.

According to the above-described second embodiment, the manifold 50 is arranged between the stacks 10, and the fuel supply hole and the air supply hole are provided above and below the manifold 50 in the stacking direction, respectively. Fuel gas and air can be evenly supplied to each cell 11 constituting one laminate 10 . As a result, there is no bias in the amount of reaction of each cell 11, and the same effect as in the first embodiment can be obtained.

In this embodiment, the number of cells 11 positioned above and below the manifold 50 (number of units) is not limited as long as the fuel gas and air are evenly supplied to these cells 11 . That is, the fuel supply holes 61a and 61b are designed so that the deviation of the flow rate is small, and the number of units of the cells 11 constituting the upper stack 10 and the lower stack 10 is changed appropriately according to this design. good.

Further, in the present embodiment, a case where one manifold 50 is provided has been described as an example, but the number is not limited, and for example, as shown in FIG. It is good also as a structure provided. In addition, by combining the present embodiment and the first embodiment, for example, as shown in FIG. Alternatively, a plurality of fuel supply holes and a plurality of air supply holes may be provided on either one of the upper side and the lower side of the manifold 50, and one fuel supply hole and one air supply hole may be provided on the other side.

While several embodiments of the invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and modifications can be made without departing from the spirit of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and equivalents thereof.

1. cell stack;10. Laminate, 11. cell 11a. anode, 11b. electrolyte, 11c. air electrode, 12 . separator, 12a. cell containing section, 13 . sealing plate, 13a. opening; 14. sealing material, 15. fuel chamber, 16. air chambers 20, 50 . Manifold, 20a, 50a. fuel inlet, 20b, 50b. air introduction part, 30, 60 . fuel supply channels, 31a, 31b, 61a, 61b . fuel supply holes, 32, 62 . fuel supply lateral hole, 35, 65 . Air supply channels, 36a, 36b, 66a, 66b . air supply holes, 37, 67 . Air supply lateral holes, 40, 70 . fuel discharge channel, 41, 71a, 71b. fuel discharge holes, 42, 72 . fuel discharge horizontal hole, 43, 73 . fuel outlet, 45, 75 . air discharge channels, 46, 76 . air exhaust holes, 47, 77 . Air discharge horizontal hole

Claims (5)

a laminate in which cells and separators are alternately laminated, and the side surfaces of the cells are surrounded by the separators;
a manifold sandwiched between the laminates and having a fuel introduction portion for introducing fuel gas from the outside and an air introduction portion for introducing air from the outside;
a fuel supply channel, which is a channel for the fuel gas supplied to the cell;
an air supply channel that is a channel for air supplied to the cell,
The cells form a first cell group and a second cell group above the manifold in the stacking direction, and form a third cell group and a fourth cell group below the manifold in the stacking direction. death,
The fuel supply channel includes a first fuel supply channel extending upward in the stacking direction from the fuel introduction portion through the separator to supply fuel gas to each cell of the first cell group; a second fuel supply passage extending upward in the stacking direction from the fuel introduction portion through the separator at a position different from the first fuel supply passage, in order to supply fuel gas to each cell of the cell group of In order to supply fuel gas to each cell of the third cell group, a third fuel supply passage extending downward in the stacking direction through the separator from the fuel introduction portion; a fourth fuel supply path extending downward in the stacking direction from the fuel introduction portion through the separator at a position different from that of the third fuel supply path, for supplying fuel gas. . In order to supply air to each cell of the first cell group, the air supply channel includes a first air supply channel extending upward in the stacking direction through the separator from the air introduction portion, and a second air supply channel. a second air supply path extending upward in the stacking direction from the air introduction portion through the separator at a position different from that of the first air supply path to supply air to each cell of the cell group; a third air supply path extending downward in the stacking direction from the air introduction portion through the separator to supply air to each cell of the fourth cell group; and supplying air to each cell of the fourth cell group and a fourth air supply path extending downward in the stacking direction from the air introduction portion through the separator at a position different from the third air supply path. chemical cell stack. a laminate in which cells and separators are alternately laminated, and the side surfaces of the cells are surrounded by the separators;
a manifold sandwiched between the laminates and having a fuel introduction portion for introducing fuel gas from the outside and an air introduction portion for introducing air from the outside;
a fuel supply channel, which is a channel for the fuel gas supplied to the cell;
an air supply channel that is a channel for air supplied to the cell,
The cells form a first cell group and a second cell group above the manifold in the stacking direction, and form a third cell group and a fourth cell group below the manifold in the stacking direction. death,
In order to supply air to each cell of the first cell group, the air supply channel includes a first air supply channel extending upward in the stacking direction through the separator from the air introduction portion, and a second air supply channel. a second air supply path extending upward in the stacking direction from the air introduction portion through the separator at a position different from that of the first air supply path to supply air to each cell of the cell group; a third air supply path extending downward in the stacking direction from the air introduction portion through the separator to supply air to each cell of the fourth cell group; and supplying air to each cell of the fourth cell group and a fourth air supply path extending downward in the stacking direction from the air introduction portion through the separator at a position different from the third air supply path. A fuel cell comprising the electrochemical cell stack according to any one of claims 1 to 3. A hydrogen production apparatus comprising the electrochemical cell stack according to any one of claims 1 to 3.

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