JP4713071B2 - Fuel cell and manufacturing method thereof - Google Patents

Description

  The present invention relates to a fuel cell, and more particularly to a solid polymer electrolyte fuel cell having a metal separator and capable of easily managing the height of a gas flow path of the separator and a method for manufacturing the same.

A solid polymer electrolyte fuel cell is composed of a laminate of a membrane-electrode assembly (MEA) and a separator (however, the lamination direction may be arbitrary). The membrane-electrode assembly includes an electrolyte membrane composed of an ion exchange membrane, an electrode composed of a catalyst layer disposed on one surface of the electrolyte membrane (anode, fuel electrode), and an electrode composed of a catalyst layer disposed on the other surface of the electrolyte membrane ( Cathode, air electrode). Between the membrane-electrode assembly and the separator, diffusion layers are provided on the anode side and the cathode side, respectively. In the separator, a fuel gas passage for supplying fuel gas (hydrogen) to the anode is formed, and an oxidizing gas passage for supplying oxidizing gas (oxygen, usually air) to the cathode. The separator is also formed with a refrigerant flow path for flowing a refrigerant (usually cooling water). A cell (unit fuel cell, also referred to as a single cell) is configured by stacking a membrane-electrode assembly and a separator, a module is configured from at least one cell, the module is stacked to form a cell stack, and the cell stack of the cell stack Terminals, insulators, and end plates are arranged at both ends in the direction, the cell stack is clamped in the cell stacking direction, and is fastened with fastening members (for example, tension plates), bolts and nuts that extend in the cell stacking direction. To do.
In each cell, a reaction for converting hydrogen into hydrogen ions (protons) and electrons is performed on the anode side, and the hydrogen ions move through the electrolyte membrane to the cathode side. On the cathode side, oxygen, hydrogen ions, and electrons (neighboring MEA) Next, the following reaction is performed to generate water from electrons generated at the anode of the first electrode through the separator or electrons generated at the anode of the cell at one end in the cell stacking direction through the external circuit to the cathode of the other cell.
Anode side: H ₂ → 2H ⁺ + 2e ⁻
Cathode side: 2H ⁺ + 2e ⁻ + (1/2) O ₂ → H ₂ O

In order to make the portion to which the fuel gas is supplied and the portion to which the oxidant gas is supplied face each other through the electrolyte and to generate power efficiently, the fuel gas passage and the oxidant gas passage may extend in parallel through the electrolyte. desirable. In addition, in order to manufacture the separator at low cost and with high productivity, the separator is made of a metal plate, the metal plate is press-molded so as to be corrugated in the thickness direction, and the gas flow path is formed from the concave portion of the press molding. It is desirable to form.
In order to satisfy these requirements, Japanese Patent Laid-Open No. 2000-173631 discloses that a separator of an adjacent unit fuel cell is a metal separator, a flow path is formed from the recess, and one of the separators is used to increase the conductivity between the separators. The top part of the convex part of a separator and the top part of the convex part of the other separator are faced | matched, and what contacted with the electroconductive adhesive agent is proposed.

However, the straight gas flow path of the corrugated metal separator makes it difficult to accurately measure the dimensions due to the characteristics of the corrugated sheet. As shown in the figure, the convex portions 3 and 4 of the corrugated plates 1 and 2 cause a positional deviation Δw, a height deviation Δh depending on the location, and the pressing force between the separator and between the separator and the diffusion layer becomes difficult to manage Increases contact resistance due to defects.
JP 2000-173631 A

The problem to be solved by the present invention is a problem of contact failure and increase in contact resistance due to misalignment between convex portions of metal separators adjacent to each other in the unit fuel cell stacking direction of a conventional fuel cell.
An object of the present invention is to provide a fuel cell that does not cause or hardly causes contact failure and contact resistance increase due to misalignment between adjacent convex portions of separators in the unit fuel cell stacking direction, and a method for manufacturing the same.

The present invention for solving the above problems and achieving the above object is as follows.
(1) (a) A unit fuel cell in which an MEA is sandwiched between a first separator having a first gas channel on the MEA side and a second separator having a second gas channel on the MEA side A fuel cell comprising a plurality of stacked layers,
(B) the first gas flow path of the first separator and the second gas flow path of the second separator have parallel flow path portions extending in parallel with each other;
(C) The surfaces of the first separator and the second separator that are in contact with the second or first separator of the adjacent unit fuel cell are corrugated in the stacking direction of the unit fuel cells. ,
(D) The parallel flow path portion of the first gas flow path of the first separator and the second gas flow path of the second separator of the adjacent unit fuel cell facing the first separator. The parallel flow path portion is formed in a shape that is uneven in the cell in-plane direction and in the direction perpendicular to the flow path extension direction so as to cross each other multiple times obliquely ,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
Fuel cell.
(2) (A) The MEA is sandwiched between a first separator having a plurality of first gas flow paths on the MEA side and a second separator having a plurality of second gas flow paths on the MEA side. A fuel cell constructed by stacking a plurality of unit fuel cells,
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell,
(D) The first gas flow path and the second gas flow path are formed in a shape that is uneven in a cell in-plane direction and in a direction perpendicular to the flow path extension direction, crossing at least one multiple diagonal of the second gas flow path of the second separator unit fuel cell of the neighboring each of said first gas flow path, at a site which intersects the diagonal, the first And the second separator of the adjacent unit fuel cell are in contact with each other,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
Fuel cell.
(3) (A) The MEA is sandwiched between a first separator having a plurality of first gas flow paths on the MEA side and a second separator having a plurality of second gas flow paths on the MEA side. A fuel cell constructed by stacking a plurality of unit fuel cells,
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell,
(D) The first gas flow path and the second gas flow path are formed in a shape that is uneven in a cell in-plane direction and in a direction perpendicular to the flow path extension direction, and the plurality of first gases the channel intersects with at least one multiple diagonal of the second gas flow path of the second separator via the MEA, respectively, in the point of intersection to the diagonal, said second separator and said first separator Holds the MEA ,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
Fuel cell.
(4) (a) a first separator provided with a plurality of first gas flow paths having a waveform in the cell in-plane direction and in a direction perpendicular to the flow path extension direction on the MEA side;
(D) a second separator provided on the MEA side with a plurality of second gas passages having a waveform that undulates in a cell in-plane direction and in a direction orthogonal to the passage extension direction;
(A) the MEA sandwiched between the first separator and the second separator;
A fuel cell in which a plurality of unit fuel cells including
(D) The waveform has a shape in which each of the first gas flow paths intersects at least one of the second gas flow paths obliquely a plurality of times,
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell ,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
Fuel cell.
(5) (a) a first separator provided with a plurality of first gas flow paths on the MEA side;
A second separator provided with a plurality of second gas flow paths on the MEA side;
MEA sandwiched between the first separator and the second separator;
A fuel cell in which a plurality of unit fuel cells including
(D) The first gas flow path and the second gas flow path have a corrugated shape that is uneven in a direction in the cell plane and perpendicular to the extending direction of the flow path. Each of the plurality of first gas flow paths has a shape that obliquely intersects at least one of the second gas flow paths a plurality of times,
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell ,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
Fuel cell.
(6) A fuel cell which is configured by stacking a plurality of (i) unit fuel cells, that Do convex toward the unit fuel cell of one unit fuel cell is adjacent extend continuously in the cell plane direction A first separator having a first convex portion, and the first separator forms a cooling water flow path with a second separator of an adjacent unit fuel cell facing the first separator; And
(E) second separator wherein a unit fuel extends continuously to the first parallel cell plane direction and the convex portion of the first separator of the one unit fuel cell unit fuel cell of the next has a second convex portion that Do convex toward the battery, said one of said first rear surface of the convex portion of the unit fuel cell is a concave toward the MEA side of the one unit fuel cell a first gas channel configured to have a second second gas passage have a concave back surface of the convex portion toward the MEA side of the unit fuel cell adjacent said unit fuel cell of the next Configure
(D) the first gas flow path and the second gas flow path have a corrugated shape that is concave and convex in a cell in-plane direction and in a direction perpendicular to the extension direction of the flow path; The axis of the part and the axis of the second convex part intersect with each other obliquely a plurality of times,
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell,
Fuel cell.
(7) (a) A unit fuel cell in which an MEA is sandwiched between a first separator having a first gas flow path on the MEA side and a second separator having a second gas flow path on the MEA side. A fuel cell comprising a plurality of stacked layers,
(B) the first gas flow path of the first separator and the second gas flow path of the second separator have parallel flow path portions extending in parallel with each other;
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell,
(D) The parallel flow path portion of the first gas flow path of the first separator and the second gas flow path of the second separator of the adjacent unit fuel cell facing the first separator. The parallel flow path portion is formed in a shape that is uneven in the cell in-plane direction and in the direction perpendicular to the flow path extension direction so as to cross each other multiple times obliquely,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
(F) The first gas flow path of the first separator and the second gas flow path of the second separator of the adjacent unit fuel cell facing the first separator obliquely intersect with each other. At the site, the first separator and the second separator of the adjacent unit fuel cell facing the first separator are fixed to each other,
Fuel cell.
(8) (a) A unit fuel cell in which an MEA is sandwiched between a first separator having a first gas flow path on the MEA side and a second separator having a second gas flow path on the MEA side. A fuel cell comprising a plurality of stacked layers,
(B) the first gas flow path of the first separator and the second gas flow path of the second separator have parallel flow path portions extending in parallel with each other;
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell,
(D) The parallel flow path portion of the first gas flow path of the first separator and the second gas flow path of the second separator of the adjacent unit fuel cell facing the first separator. The parallel flow path portion is formed in a shape that is uneven in the cell in-plane direction and in the direction perpendicular to the flow path extension direction so as to cross each other multiple times obliquely,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
(G) The crossing angle between the first gas flow path of the first separator and the second gas flow path of the second separator of the adjacent unit fuel cell facing the first separator is 45 degrees or more. small,
Fuel cell.
(9) The first gas flow path of the first separator and the second gas flow path of the second separator of the adjacent unit fuel cell facing the first separator obliquely intersect with each other. Any one of (1) to (6) and (8) in which the first separator and the second separator of the adjacent unit fuel cell facing the first separator are fixed to each other at the site. A fuel cell according to claim 1.
(10) The first separator is a metal plate having a corrugated portion in the stacking direction of the unit fuel cells, and the second separator has a corrugated portion in the stacking direction of the unit fuel cells. The fuel cell according to any one of (1) to (8), which is a metal plate.
(11) The fuel cell according to any one of (1) to (3), wherein the shape that is uneven in the cell in-plane direction and in a direction orthogonal to the flow path extension direction is a waveform.
(12) The gas flow in the first gas flow path of the first separator and the second gas flow path of the second separator is an opposing flow, and any one of (1) to (8) A fuel cell according to claim 1.
(13) The unevenness amount Δd of the shape of the first gas flow path and the second gas flow path that is uneven in the cell in-plane direction and in the direction perpendicular to the flow path extension direction of each gas flow path is From the misalignment tolerance Δa in the direction orthogonal to the flow path extension direction between the flow path center line of the first gas flow path and the flow path center line of the second gas flow path of the adjacent unit fuel cell. The fuel cell according to any one of (1) to (8), which is assumed to be large.
( 14 ) A fuel cell manufacturing method for manufacturing the fuel cell according to any one of (1) to (13) above, wherein the ridges and recesses for forming a flow path are formed in a cell in-plane direction. A method for manufacturing a fuel cell, comprising a step of pressing a metal plate using a press mold that is swelled in a direction orthogonal to a flow path extending direction to form the first and second separators.

According to the fuel cells of the above (1) to (8) and (13), the parallel flow path portion of the first gas flow path of the first separator and the second gas flow path of the second separator adjacent to the first gas flow path. Since the parallel flow path portions are formed in a shape that is uneven in the cell in-plane direction and in the direction perpendicular to the flow path extension direction so as to obliquely intersect each other multiple times, the flow paths are in the gas flow path extension direction. Even if the position is shifted in the direction orthogonal to the direction, the contact area between the convex portions is suppressed from decreasing. Moreover, the convex part of one separator does not enter the concave part of the other separator, and the overlapping height of the convex parts is maintained at a predetermined overlapping height. As a result, contact failure and contact resistance increase do not occur or are unlikely to occur.
According to the fuel cells of (9) and (7) above, the first gas flow path of the first separator and the second gas flow path of the second separator of the adjacent unit fuel cell are slanted. Since the first separator and the second separator of the adjacent unit fuel cell are fixed to each other at the intersecting portion, the conductivity at the intersection between the separators can be improved.
According to the fuel cell of (10) above, since the first and second separators are made of metal plates having portions that are undulated in the stacking direction of the unit fuel cells, the first gas flow path and the second gas While maintaining the parallel flow path configuration with the flow path and the easy formation of the separator and flow path by pressing, it is possible to solve the problem of contact failure and increase in contact resistance in a separator having a conventional linear gas flow path. .

According to the fuel cell of the above (11), since the shape that is uneven in the cell in-plane direction and in the direction orthogonal to the flow path extension direction is a waveform, it has almost no influence on the flow of gas and the flow of cooling water on the back side. For example, it is possible to prevent poor contact due to misalignment without increasing the pressure loss.
According to the fuel cell of the above (12), the gas flow in the first gas flow path of the first separator and the second gas flow path of the second separator is a counter flow, so the self-circulation of the generated water Can be realized effectively.
According to the manufacturing method of the fuel cell of the upper Symbol (14), the parallel flow path portion 22, the direction of the unevenness perpendicular to the flow path extending direction, the press-type flow path forming of ridges, a concave, flow It can be easily obtained by undulation in a direction orthogonal to the road extending direction.

Below, the fuel cell of this invention and its manufacturing method are demonstrated with reference to FIGS. 1-3.
The fuel cell 10 of the present invention is, for example, a polymer electrolyte fuel cell, and the MEA 11 includes a first separator 13 having a first gas channel 12 and a second separator 15 having a second gas channel 14. The fuel cell is configured by stacking a plurality of unit fuel cells 16 sandwiched between the two (however, the stacking direction may be arbitrary).
Here, the MEA 11 is a membrane electrode assembly in which an electrolyte 17 is sandwiched between an anode 18 and a cathode 19. Diffusion layers 20 and 21 may be provided between the MEA 11 and the separators 13 and 15. The first separator 13 having the first gas flow path 12 is one of an anode side separator having a fuel gas flow path and a cathode side separator having an oxidizing gas flow path. The second separator 15 is the other of an anode side separator having a fuel gas flow path and a cathode side separator having an oxidizing gas flow path. When the first separator 13 having the first gas flow path 12 is an anode side separator having a fuel gas flow path, the second separator 15 having the second gas flow path 14 is used as the oxidizing gas flow path. When the first separator 13 having the first gas flow path 12 is a cathode side separator having the oxidizing gas flow path, the second separator having the second gas flow path 14 is used. The separator 15 is an anode side separator having a fuel gas flow path.

  Of the first gas flow path 12 and the second separator 15 of the first separator 13 (may be the second separator 15 of the same unit fuel cell or the second separator 15 of the adjacent unit fuel cell) The second gas flow path 14 has parallel flow path portions 22 extending in parallel with each other in at least a part of the flow paths. The parallel flow path portion 22 of the first gas flow path 12 of the first separator 13 and the parallel flow path portion 22 of the second gas flow path 14 of the second separator 15 adjacent to the first separator 13 are: It is formed in an uneven shape in the in-plane direction of the cell (unit fuel cell) and in the direction perpendicular to the flow path extension direction so as to cross each other obliquely. Reference numeral 23 denotes an intersection. “Diagonal intersection” does not include “orthogonal”. It is preferable to intersect at an angle smaller than 45 degrees. The amount Δd of the parallel flow path portion 22 that is uneven in the direction orthogonal to the flow path extension direction is the sum of the top of the ridges of the first gas flow path 12 and the top of the ridges of the second gas flow path 14. What is necessary is just to be larger than the maximum deviation amount in the direction orthogonal to the flow path extension direction (maximum deviation amount due to manufacturing error or assembly error, that is, positional deviation allowable error Δa).

The 1st separator 13 is a metal separator which consists of a metal plate which has a part uneven | corrugated in the waveform direction in the lamination direction of a unit fuel cell. Similarly, the 2nd separator 15 is a metal separator which consists of a metal plate which has a part uneven | corrugated in the waveform direction in the lamination direction of a unit fuel cell. The concave and convex ridges and ridges extend continuously in the flow path extending direction. The channels 12 and 14 may be substantially straight channels or serpentine channels.
In the fuel cell manufacturing method of the present invention, the flow paths 12 and 14 are formed by pressing when the metal separator is press-formed. The unevenness in the direction perpendicular to the flow path extension direction of the parallel flow path portion 22 is obtained by undulating the ridges and depressions for forming the press-type flow path in the direction perpendicular to the flow path extension direction. Easy to get.

  The shapes of the first gas flow channel 12 and the second gas flow channel 14 that are concave and convex in the direction in the cell plane and in the direction perpendicular to the flow channel extension direction are desirably wavy. In addition, it is desirable to determine the length of one wave so that a plurality of intersecting portions 23 appear in one parallel flow path portion 22.

  A portion where the first gas flow path 12 of the first separator 13 of one unit fuel cell 16 and the second gas flow path 14 of the second separator 16 of the adjacent unit fuel cell 16 intersect diagonally. At the (intersection portion 23), the first separator 13 and the second separator 15 of the adjacent unit fuel cell 16 may be fixed to each other. Reference numeral 24 denotes a fixing portion at the intersection 23. However, in the same unit fuel cell 16, there is a membrane 17 between the first separator 13 and the second separator 15, so at the intersection 23, the first separator 13 and the second separator 15 Cannot be fixed. In order to increase the electrical conductivity between the separators at the intersection 23, it is preferable that the fixing is performed by any one of brazing, welding, conductive adhesive, and the like.

  In the parallel flow path portion 22, the second separator 15 is opposed to the first gas flow path 12 of the first separator 13 and the adjacent unit fuel cell 16 or the same unit fuel cell 16 through the membrane 17. The gas flow in the second gas flow path 14 is preferably a counter flow. In the counter flow, water generated by power generation on the cathode 19 side passes through the MEA 11 and moves to the anode 18 side, and the water moves downstream along the flow of the anode side flow path, while the upstream of the cathode 19 side is dried. Moisture self-circulation that creates an appropriate wet state of the MEA 11 can be realized by soaking into the MEA 11 at an easy position. When the MEA is too dry, the internal resistance increases and the loss becomes excessive. When the MEA becomes too wet, the gas diffusion is inhibited by water and the catalytic reaction site is covered, thereby causing a deterioration in performance.

Next, the operation and effect of the fuel cell of the present invention will be described.
The parallel flow path portion 22 of the first gas flow path 12 of the first separator 13 and the parallel flow path portion 22 of the second gas flow path 14 of the second separator 15 intersect each other at an intersection 23. as to, because it is shaped to unevenness in the direction perpendicular to the and channel extension direction cell plane direction, the flow channel 12, 14 with each other is misaligned in a direction perpendicular to the gas flow path extending direction also, it is possible to suppress the area of contact between the convex portion is reduced. Moreover, the convex part of one separator does not enter the concave part of the other separator. Thereby, the overlapping height between the convex portions is maintained at a predetermined overlapping height. As a result, contact failure and contact resistance increase between separators or between the separator and the diffusion layer do not occur or hardly occur.

Further, at a portion (intersection) 23 where the first gas flow path 12 of the first separator 13 and the second gas flow path 14 of the second separator 15 of the adjacent unit fuel cell 16 intersect obliquely. In the case where the first separator 13 and the second separator 15 of the adjacent unit fuel cell are fixed to each other, the conductivity at the intersection 23 between the separators 13 and 15 can be improved. As a result, the contact failure and the contact resistance increase between the separators do not occur or hardly occur.

  Since the first and second separators 13 and 15 can be made of corrugated metal separators, the performance of the fuel cell is maintained by the parallel flow path configuration of the first gas flow path 12 and the second gas flow path 14, and the press Good productivity due to the formation of the flow paths 12 and 14 can be maintained. Further, in the conventional linear gas flow path, there has been a problem of contact failure and contact resistance increase, but in the present invention, the contact in the conventional linear gas flow path is caused by the oblique intersection of the flow paths 12 and 14. The problem of defects and increased contact resistance can be solved.

In addition, by forming the corrugated shape in the cell in-plane direction and in the direction orthogonal to the flow path extension direction, the pressure loss of the gas flow and the cooling water flow on the back surface thereof is hardly increased.
Further, the self-circulation of the produced water is effectively achieved by making the gas flow in the first gas flow path 12 of the first separator 13 and the second gas flow path 14 of the second separator 15 counter flow. Can be realized. As a result, it is not necessary to mount the humidifying tank on the vehicle, or a small tank can be used even if it is mounted.

The front view of the part of separator which shows the positional relationship of the 1st, 2nd gas flow path of the 1st, 2nd separator of the fuel cell of this invention, or the fuel cell manufactured by the manufacturing method of the fuel cell of this invention It is. It is a side view of the fuel cell of the present invention. FIG. 3 is a cross-sectional view of a portion of the fuel cell of FIG. 1 is a cross-sectional view of a fuel cell with a conventional corrugated metal separator showing a height shift. FIG.

10 Fuel cell 11 MEA
12 1st gas flow path 13 1st separator 14 2nd gas flow path 15 2nd separator 16 Unit fuel cell 17 Electrolyte (electrolyte membrane)
18 Anode 19 Cathode 20, 21 Diffusion layer 22 Parallel flow path portion 23 Crossing portion 24 Adhering portion

Claims (14)

(A) A plurality of unit fuel cells in which an MEA is sandwiched between a first separator having a first gas flow path on the MEA side and a second separator having a second gas flow path on the MEA side are stacked. A fuel cell configured as follows:
(B) the first gas flow path of the first separator and the second gas flow path of the second separator have parallel flow path portions extending in parallel with each other;
(C) The surfaces of the first separator and the second separator that are in contact with the second or first separator of the adjacent unit fuel cell are corrugated in the stacking direction of the unit fuel cells. ,
(D) The parallel flow path portion of the first gas flow path of the first separator and the second gas flow path of the second separator of the adjacent unit fuel cell facing the first separator. The parallel flow path portion is formed in a shape that is uneven in the cell in-plane direction and in the direction perpendicular to the flow path extension direction so as to cross each other multiple times obliquely ,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
Fuel cell. (A) Unit fuel in which the MEA is sandwiched between a first separator having a plurality of first gas flow paths on the MEA side and a second separator having a plurality of second gas flow paths on the MEA side A fuel cell configured by stacking a plurality of batteries,
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell,
(D) The first gas flow path and the second gas flow path are formed in a shape that is uneven in a cell in-plane direction and in a direction perpendicular to the flow path extension direction, crossing at least one multiple diagonal of the second gas flow path of the second separator unit fuel cell of the neighboring each of said first gas flow path, at a site which intersects the diagonal, the first And the second separator of the adjacent unit fuel cell are in contact with each other,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
Fuel cell. (A) Unit fuel in which the MEA is sandwiched between a first separator having a plurality of first gas flow paths on the MEA side and a second separator having a plurality of second gas flow paths on the MEA side A fuel cell configured by stacking a plurality of batteries,
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell,
(D) The first gas flow path and the second gas flow path are formed in a shape that is uneven in a cell in-plane direction and in a direction perpendicular to the flow path extension direction, and the plurality of first gases the channel intersects with at least one multiple diagonal of the second gas flow path of the second separator via the MEA, respectively, in the point of intersection to the diagonal, said second separator and said first separator Holds the MEA ,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
Fuel cell. (A) a first separator provided on the MEA side with a plurality of first gas passages having a waveform that undulates in a cell in-plane direction and in a direction orthogonal to the passage extension direction;
(D) a second separator provided on the MEA side with a plurality of second gas passages having a waveform that undulates in a cell in-plane direction and in a direction orthogonal to the passage extension direction;
(A) the MEA sandwiched between the first separator and the second separator;
A fuel cell in which a plurality of unit fuel cells including
(D) The waveform has a shape in which each of the first gas flow paths intersects at least one of the second gas flow paths obliquely a plurality of times,
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell ,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
Fuel cell. (A) a first separator provided with a plurality of first gas flow paths on the MEA side;
A second separator provided with a plurality of second gas flow paths on the MEA side;
MEA sandwiched between the first separator and the second separator;
A fuel cell in which a plurality of unit fuel cells including
(D) The first gas flow path and the second gas flow path have a corrugated shape that is uneven in a direction in the cell plane and perpendicular to the extending direction of the flow path. Each of the plurality of first gas flow paths has a shape that obliquely intersects at least one of the second gas flow paths a plurality of times,
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell ,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
Fuel cell. A fuel cell is configured by stacking a plurality of (i) unit fuel cell, first that Do a convex one unit fuel cell toward the unit fuel cell adjacent extend continuously in the cell surface direction A first separator having a convex portion, and the first separator forms a cooling water flow path with a second separator of an adjacent unit fuel cell facing the first separator;
(E) second separator wherein a unit fuel extends continuously to the first parallel cell plane direction and the convex portion of the first separator of the one unit fuel cell unit fuel cell of the next has a second convex portion that Do convex toward the battery, said one of said first rear surface of the convex portion of the unit fuel cell is a concave toward the MEA side of the one unit fuel cell a first gas channel configured to have a second second gas passage have a concave back surface of the convex portion toward the MEA side of the unit fuel cell adjacent said unit fuel cell of the next Configure
(D) the first gas flow path and the second gas flow path have a corrugated shape that is concave and convex in a cell in-plane direction and in a direction perpendicular to the extension direction of the flow path; The axis of the part and the axis of the second convex part intersect with each other obliquely a plurality of times,
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell,
Fuel cell. (A) A plurality of unit fuel cells in which an MEA is sandwiched between a first separator having a first gas flow path on the MEA side and a second separator having a second gas flow path on the MEA side are stacked. A fuel cell configured as follows:
(B) the first gas flow path of the first separator and the second gas flow path of the second separator have parallel flow path portions extending in parallel with each other;
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell,
(D) The parallel flow path portion of the first gas flow path of the first separator and the second gas flow path of the second separator of the adjacent unit fuel cell facing the first separator. The parallel flow path portion is formed in a shape that is uneven in the cell in-plane direction and in the direction perpendicular to the flow path extension direction so as to cross each other multiple times obliquely,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
(F) The first gas flow path of the first separator and the second gas flow path of the second separator of the adjacent unit fuel cell facing the first separator obliquely intersect with each other. At the site, the first separator and the second separator of the adjacent unit fuel cell facing the first separator are fixed to each other,
Fuel cell. (A) A plurality of unit fuel cells in which an MEA is sandwiched between a first separator having a first gas flow path on the MEA side and a second separator having a second gas flow path on the MEA side are stacked. A fuel cell configured as follows:
(B) the first gas flow path of the first separator and the second gas flow path of the second separator have parallel flow path portions extending in parallel with each other;
(C) The surface of the first separator and the second separator on the side in contact with the second or first separator of the adjacent unit fuel cell facing the first separator and the second separator, The unit fuel cell is uneven in the laminating direction of the fuel cell,
(D) The parallel flow path portion of the first gas flow path of the first separator and the second gas flow path of the second separator of the adjacent unit fuel cell facing the first separator. The parallel flow path portion is formed in a shape that is uneven in the cell in-plane direction and in the direction perpendicular to the flow path extension direction so as to cross each other multiple times obliquely,
(E) The surfaces of the first and second separators that are in contact with the second and first separators of the adjacent unit fuel cells are directed toward the second and first separators of the adjacent unit fuel cells. The back surface of the convex portion is concave toward the MEA, and constitutes the first and second gas flow paths of the first and second separators, respectively.
(G) The crossing angle between the first gas flow path of the first separator and the second gas flow path of the second separator of the adjacent unit fuel cell facing the first separator is 45 degrees or more. small,
Fuel cell.   In the part intersecting at an angle between the first gas flow path of the first separator and the second gas flow path of the second separator of the adjacent unit fuel cell facing the first separator, The fuel according to any one of claims 1 to 6 and 8, wherein the first separator and the second separator of the adjacent unit fuel cell facing the first separator are fixed to each other. battery.   The first separator is a metal plate having a undulating portion in the stacking direction of the unit fuel cells, and the second separator is a metal plate having a undulating portion in the stacking direction of the unit fuel cells. The fuel cell according to any one of claims 1 to 8.   The fuel cell according to any one of claims 1 to 3, wherein the shape that is concave and convex in the cell in-plane direction and in a direction orthogonal to the flow path extension direction is a waveform.   The fuel according to any one of claims 1 to 8, wherein a gas flow in the first gas flow path of the first separator and the second gas flow path of the second separator is a counter flow. battery.   The unevenness amount Δd of the first gas flow path and the second gas flow path, each of which is uneven in the cell in-plane direction and in the direction perpendicular to the flow path extension direction, is the first gas flow path and the second gas flow path. The misalignment tolerance Δa in the direction orthogonal to the flow path extension direction between the flow path center line of one gas flow path and the flow path center line of the second gas flow path of the adjacent unit fuel cell is made larger. The fuel cell according to any one of claims 1 to 8.   A fuel cell manufacturing method for manufacturing the fuel cell according to any one of claims 1 to 13, wherein the ridges and ridges for channel formation are orthogonal to the channel extension direction in the cell in-plane direction. A method of manufacturing a fuel cell, comprising a step of pressing the metal plate using a press mold that is swelled in a direction to form the first and second separators.

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