JP2006120655A - Separator for fuel cell - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a separator for a fuel cell having a flow passage without difference of level in thickness direction of a frame. <P>SOLUTION: In a separator 18 for a fuel cell with a resin frame having a resin frame 31 incorporating a manifold 29 in the surrounding of the separator 18, the separator 18 is made of metal, an outer edge part of the separator 18 extends into the frame 31 and stops at this side of the manifold 29 formed in the frame 31 and also embedded in the frame 31 to be formed integrally therewith, and a tunnel-shaped channel 33 communicating the manifold 29 with the inside space of the internal circumferential face of the frame 31 is formed in the internal circumferential side of the manifold 29 of the frame 31. The inside face of the separator side part of the channel 33 is flush with the surface of the separator 18. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a fuel cell separator having a resin frame on the outer peripheral portion and a tunnel-like flow path in the frame.

The solid polymer electrolyte fuel cell is arranged on the other side of the electrolyte membrane, which is an electrolyte membrane made of an ion exchange membrane, an electrode (anode, fuel electrode) made of a catalyst layer and a diffusion layer arranged on one side of the electrolyte membrane, and the electrolyte membrane. Membrane-Electrode Assembly (MEA) consisting of an electrode (cathode, air electrode) consisting of a catalyst layer and a diffusion layer, and fuel gas (hydrogen) and oxidizing gas (oxygen, usually air) at the anode and cathode A cell is formed from a fluid passage for supplying a liquid or a separator that forms a flow path for flowing a cooling medium, a module is formed from a stack of a plurality of cells, and the modules are stacked to form a module group. A stack is formed by arranging terminals, insulators, and end plates at both ends of the cell stacking direction. It consists of what was fastened and fixed by the fastening member (for example, tension plate) extended in a layered body lamination direction.
In a solid polymer electrolyte fuel cell, a reaction for converting hydrogen into hydrogen ions and electrons is performed on the anode side, the hydrogen ions move through the electrolyte membrane to the cathode side, and oxygen, hydrogen ions and electrons (adjacent to the cathode side). The electrons produced at the anode of the MEA come through the separator) to produce water.
Anode side: H ₂ → 2H ⁺ + 2e ⁻
Cathode side: 2H ⁺ + 2e ⁻ + (1/2) O ₂ → H ₂ O
Since heat is generated in the water generation reaction at the cathode, a flow path through which a cooling medium (usually cooling water) flows is formed in the separator for each cell or a plurality of (for example, two) cells. And cooling the fuel cell.
Japanese Patent Application Laid-Open No. 8-162131 has a resin frame around a metal separator, and a fuel gas and an oxidant gas are formed on each metal separator through a flow path formed in the resin frame from each manifold formed in the resin frame. A fuel cell separator that supplies and discharges the fuel gas channel and the oxidizing gas channel is disclosed. Since the MEA film is sandwiched between the resin frames and sealed, it is not desirable in terms of sealing that the flow path is exposed in a groove shape on the surface of the resin frame and the sealing surface is uneven. Therefore, the flow path formed in the resin frame is a composite frame of two frames by forming a groove-like flow path in two frames and bonding the two frames together with the groove-like flow path. Is formed inside. The channel is bent in the frame thickness direction in the middle in order to communicate with the reaction gas channel on one side surface of the separator, and there is a step in the channel at the bent part.
JP-A-8-162131

However, the conventional fuel cell separator has the following problems.
(i) Since the flow path in the composite frame is formed by bonding the two plates, the sealing of the bonding surface of the two plates becomes a new problem. In addition, the number of frames is doubled, and manufacturing costs, assembly costs, and the like are greatly increased.
(ii) The flow path from the manifold to the reaction gas flow path on the one side surface of the separator has a step bent in the frame plate thickness direction, and the smoothness of the flow of the reaction gas is hindered.
An object of the present invention is to provide a fuel cell separator in which a flow path having no step is formed within the thickness of one frame.

The present invention for achieving the above object is as follows.
(1) In a fuel cell separator with a resin frame having a resin frame with a built-in manifold around the separator,
The separator is a metal separator, an outer edge portion of the separator extends into the resin frame and stops in front of a manifold formed in the resin frame, and the outer edge portion of the separator is embedded in the resin frame and It is molded integrally with the frame,
A tunnel-like flow path that connects the manifold and the inner space of the inner peripheral surface of the resin frame is formed on the inner peripheral portion of the resin frame from the manifold.
A fuel cell separator.
(2) The fuel cell separator according to claim 1, wherein the flow path extends linearly over the entire length of the flow path, and the inner surface of the separator side portion of the flow path is flush with the surface of the separator. .

According to the fuel cell separator of the above (1), since the tunnel-like flow path is formed in the resin frame, they are overlapped as in the case of the flow path formed by stacking two conventional grooved frames. Sealing between the frames does not become a problem, and the number of frames that has conventionally been two is one, so that the cost can be reduced. Since the outer edge portion of the metal separator is embedded in the resin frame, corrosion is suppressed without being exposed to the gas flow path or the outside.
According to the fuel cell separator of (2) above, the flow path extends linearly over the entire length of the flow path, and the inner surface of the separator side portion of the flow path is flush with the surface of the separator. The flow resistance is reduced as compared with the conventional flow path.

Below, the separator for fuel cells of this invention is demonstrated with reference to FIGS.
The fuel cell of the present invention is a solid polymer electrolyte fuel cell 10. The fuel cell 10 of the present invention is mounted on, for example, a fuel cell vehicle. However, it may be used other than an automobile.

  As shown in FIGS. 1 to 6, the solid polymer electrolyte fuel cell 10 includes an electrolyte membrane 11 made of an ion exchange membrane and an electrode 14 made up of a catalyst layer 12 and a diffusion layer 13 disposed on one surface of the electrolyte membrane 11. (Anode, fuel electrode) and a membrane-electrode assembly (MEA) comprising an electrode 17 (cathode, air electrode) comprising a catalyst layer 15 and a diffusion layer 16 disposed on the other surface of the electrolyte membrane 11; A separator 18 that forms a fluid passage 27 for supplying a fuel gas (hydrogen) and an oxidizing gas (oxygen, usually air) to the electrodes 14 and 17 and a cooling water passage 26 through which cooling water for cooling the fuel cell flows. A module is formed by stacking a plurality of cells to form a module 19 (for example, 2 modules to 1 module), and the modules 19 are stacked to form a module group. The stack 20 is configured by disposing the terminal 20, the insulator 21, and the end plate 22 at both ends of the module group in the cell stacking direction (fuel cell stacking direction). It consists of a fastening member 24 (for example, a tension plate, a through bolt, etc.) extending in the stacking direction and a bolt 25 or a nut.

  The catalyst layers 12 and 15 are made of carbon (C) containing platinum (Pt). The diffusion layers 13 and 16 are made of C. The separator 18 is impermeable and is usually made of carbon (including the case of graphite), metal, or conductive resin. Although the case where the separator 18 consists of a some metal plate is shown below, it is not restricted to this.

The separator 18 partitions any one of the fuel gas and the oxidizing gas, the fuel gas and the cooling water, and the oxidizing gas and the cooling water, and forms an electrical passage through which electrons flow from the anode of the adjacent cell to the cathode.
The cooling water channel 26 is provided for each cell or for each of a plurality of cells. For example, as shown in FIG. 3, in the case where one module is constituted by two cells, one cooling water flow path 26 is provided for each module (every two cells).

The separator 18 includes two types of separators: a cooling separator 18A that forms a cooling water passage for cooling the fuel cell and a reaction gas passage, and a reaction gas separator 18B that forms a reaction gas passage. is there.
When the separator 18 is made of a metal plate, both the cooling separator 18A and the reaction gas separator 18B are made of a metal separator in which a plurality of metal plates are stacked. The metal plate is made of, for example, a SUS (stainless steel) plate plated with nickel.

  In the case where the separator 18 is made of a metal plate, the cooling separator 18A is formed between the two metal plates 18a and 18b that are uneven and have the gas flow path 27 on the outer surface, and the two metal plates 18a and 18b. There are a total of three metal plates sandwiched between and formed with unevenness, and an intermediate metal plate 18c that forms the cooling water channel 26 on the front and back sides. The intermediate metal plate 18c may be formed with unevenness (however, it may not be formed), and the case where the unevenness is formed will be shown below. The irregularities of the metal plates 18a and 18b are, for example, dimples (the frustoconical shape of the cross section, and each irregularity is a non-continuous irregularity) (however, it may be a continuous groove-shaped irregularity), and the irregularities of the intermediate metal plate 18c are continuous. It is a groove-shaped unevenness. The intermediate metal plate 18c is in contact with the inner surface of the bottom wall of the concave and convex portions of the metal plates 18a and 18b, and supports the metal plates 18a and 18b.

  When the separator 18 is made of a metal plate, in the cooling separator 18A, the space between the two metal plates 18a and 18b is the cooling water flow path 26. The cooling water channel 26 is partitioned by the intermediate metal plate 18c into a cooling water channel 26a on the front side of the intermediate metal plate 18c and a cooling water channel 26b on the back side of the intermediate metal plate 18c. The concave and convex concave widths of the intermediate metal plate 18c are equal to each other, and the flow resistances of the front cooling water passage 26a and the rear cooling water passage 26b are equal or substantially equal. Then, the cooling water enters the cooling water passage 26 on the front and back of the metal plate 18c from the cooling water manifold 28 formed in the frame 31 outside the intermediate metal plate 18c, passes through the cooling water passages 26a and 26b, and then cools down. Exit to water manifold 28. The intermediate metal plate 18c is formed with a hole 30 that communicates the cooling water passage 26a on the front side and the cooling water passage 26b on the back side so that gas can be easily vented. Moreover, in order to give electric corrosion resistance, the metal plates 18a and 18b and the intermediate metal plate 18c are made of the same material.

  In the cooling separator 18A, the outer peripheral portions of the metal plates 18a and 18b extend into the resin-made flat frame 31 and stop before the gas manifold 29 formed in the frame 31, respectively. (E.g., embedded and insert molded). The outer peripheral portion of the intermediate metal plate 18 c stops at or near the inner peripheral surface of the frame 31 and does not extend into the frame 31. The intermediate metal plate 18c is in contact with the metal plates 18a and 18b, but is not joined by welding or the like. When the frame in which the outer peripheral portion of the metal plate 18a is embedded and the frame in which the outer peripheral portion of the metal plate 18b is embedded are separated, the intermediate metal plate 18c can be removed and replaced. A gasket 32 is disposed between the frame in which the outer peripheral portion of the metal plate 18a is embedded and the frame in which the outer peripheral portion of the metal plate 18b is embedded, and seals the cooling water passage 26 from the outside. . Further, a tunnel-like flow path 33 is formed in the frame 31, and each reaction gas (fuel gas, oxidation gas) from the gas manifold 29 is supplied to each gas flow path 27 (fuel gas flow path 27a, oxidation gas). Supply and discharge to the flow path 27b).

The reactive gas separator 18B has only two metal plates 18a and 18b that are formed with irregularities and form gas flow paths 27 (fuel gas flow paths 27a and oxidant gas flow paths 27b) on the outer surface, and an intermediate metal plate 18c. Does not have. In the reactive gas separator 18B, cooling water does not flow between the two metal plates 18a and 18b. The irregularities of the metal plates 18a and 18b are, for example, dimples (the frustoconical cross section and the irregularities are non-continuous irregularities) (however, they may be continuous groove-shaped irregularities).
In the reactive gas separator 18 </ b> B, the outer peripheral portions of the two metal plates 18 a and 18 b are combined and embedded in one frame 31. The outer peripheral portions of the combined metal plates 18 a and 18 b are stopped before the gas manifold 29 in the frame 31. Further, a tunnel-like flow path 33 is formed in the frame 31, and each reaction gas (fuel gas, oxidation gas) from the gas manifold 29 is supplied to each gas flow path 27 (fuel gas flow path 27a, oxidation gas). Supply and discharge to the flow path 27b).

In the cooling separator 18A, the membrane-electrode assembly (MEA) is sandwiched between the concave and convex portions of the metal plate 18a (18b) and the concave and convex portions of the metal plates 18a and (18b) of the reactive gas separator 18B. The electrode part is directly cooled by cooling water on the back side of the convex part.
The outer peripheral portion of the membrane-electrode assembly (MEA) is sandwiched between adjacent frames 31, and the membrane 11 extends further to the outer periphery than the electrodes 14, 17 and is sandwiched between adjacent frames 31.

5 and 6 show the structure of the resin frame 31, the separator 18, and the tunnel-like flow path 33 in the fuel cell separator 18 having a resin frame having a resin frame 31 having a manifold 29 built around the separator 18. It is shown enlarged.
The outer edges of the metal plates 18a and 18b of the separator 18 (in the case where the separator 18 is made of graphite, the graphite plate) are the gas of the resin-made frame 31 made up of a substantially rectangular flat frame with the central portion removed. When the frame 31 is formed, it is integrally formed (for example, embedded and insert-molded) on the inner peripheral side portion from the manifold 29. As for the metal plates 18a and 18b, one metal plate may be insert-molded into one frame 31 as in the cooling separator 18A, or two metal plates as in the reaction gas separator 18B. 18a and 18b may be combined and insert-molded into one frame 31.

A tunnel-like flow path 33 that connects the manifold 29 and a space through which the reaction gas (fuel gas or oxidizing gas) inside the resin frame inner peripheral surface flows is formed on the inner peripheral side portion of the resin frame 31 from the gas manifold 29. Has been. The flow path 33 is formed by a core (pin-shaped core) when the resin frame 31 is molded, and is formed within the thickness range of one frame 31. Therefore, it is not a flow path consisting of a groove in a frame in which two plates are bonded together as in the prior art.
The flow path 33 extends linearly over the entire length of the flow path, and is not bent in the plate thickness direction of the frame unlike the conventional flow path. Since the flow path 33 extends linearly, the pin-shaped core can be pulled out in the direction of the core during molding.
The inner surface of the flow path 33 on the separator 18 side is flush with the surface of the separator 18. Therefore, the separator 18 and the core do not interfere during molding.

The above-described resin frame 31 having a manifold 29 built in the periphery of the separator 18 is provided, and a tunnel-like shape that connects the manifold 29 and the inner space on the inner peripheral surface of the resin frame to the inner peripheral side portion of the resin frame 31 is provided. The fuel cell separator with a resin frame in which the flow path 33 is formed is manufactured in accordance with the following first stage process and then the second stage process to be executed.
In the first step, a pin-shaped core for tunnel-shaped flow path molding is placed in a frame intermediate product molding mold, molten resin is injected, the resin is solidified and removed from the mold, and the core is removed. 5 has a tunnel-like flow path 33 on the inner peripheral side portion of the manifold 29, and a portion of the outer peripheral side portion from the manifold 29 where the core interferes when the core is removed (a portion surrounded by a two-dot chain line B in FIG. 5). Form missing frame intermediates.
In the second stage process, the frame intermediate product manufactured in the first stage process is placed in the mold for molding the final frame product, molten resin is injected, and the portion that is lost to interfere with the core removal (see FIG. 5). The portion surrounded by a two-dot chain line B) is filled, and after the resin is solidified, it is removed from the mold to form a final frame product.
Thus, the frame portion is formed in two stages.

In the above description, the case where the separator 18 is a metal separator has been mainly described. However, the separator 18 is not limited to a metal separator, and may be any gas or liquid that is impermeable and conductive, such as a graphite separator. A conductive resin separator may be used.
Moreover, although the flow path 33 demonstrated the case where it was a flow path which connects the gas manifold 29 and a reactive gas flow path, it is not restricted to it, It connects the cooling water manifold 28 and the cooling water flow path 26 in a separator. It may be a flow path.

Next, the operation of the fuel cell separator of the present invention will be described.
Since the tunnel-like flow path 33 is formed in the resin frame 31, there is no problem with the seal between the stacked frames as in the case of the flow path formed by overlapping two conventional grooved frames. . In addition, since the composite frame formed by pasting two frames together is a single integrated frame 31 in the present invention, the cost can be reduced by simplifying the manufacturing and reducing the number of parts. .
In addition, the flow path 33 extends linearly over the entire length of the flow path, and the inner surface of the separator 18 side portion of the flow path 33 is flush with the surface of the separator 18, so that the conventional flow path that has been bent is used. Compared to the above, the flow resistance is reduced.
In addition, since the flow path 33 is formed within the thickness range of the frame 31 and the flow path 33 is not exposed to the laminated surface 34 of the frame 31, the sealing surface of the MEA electrolyte membrane 11 is flat and adjacent. The membrane 11 can be sandwiched between the flat sealing surfaces of the frame 31 for sealing. If the unevenness of the flow path is exposed in a groove shape on the seal surface, the film falls into the groove and a seal failure occurs, but such a situation does not occur. In FIG. 5, there is a step 35 on the inner peripheral portion of the laminated surface 34 of the frame 31, which is a step for absorbing the step between the MEA diffusion layer and the film 11, and outside the step 35. The electrolyte membrane 11 extends and is sealed between the planar sealing surfaces of adjacent frames 31.

  In the method for manufacturing the fuel cell separator 18 according to the present invention, the frame 31 is formed in a two-stage process including a step of forming the flow path 33 using a pin-shaped core and a step of filling the outer portion of the manifold 29. The flow path 33 can be easily formed in one frame 31.

It is the whole fuel cell schematic provided with the separator of the example of the present invention. It is sectional drawing of the edge part of the module of the fuel cell of this invention Example, and its vicinity. It is a partial expanded sectional view of the electrolyte membrane electrode assembly of the fuel cell of this invention Example. It is a front view of the intermediate metal plate of the separator for cooling of the example of the present invention. It is sectional drawing (AA sectional drawing of FIG. 6) of the vicinity part of the separator of this invention Example, a resin frame, and a tunnel-shaped flow path. It is a front view of the vicinity part of the separator of this invention Example, a resin frame, and a tunnel-shaped flow path.

Explanation of symbols

10 (solid polymer electrolyte type) fuel cell 11 electrolyte membrane 12 catalyst layer 13 diffusion layer 14 electrode (anode, fuel electrode)
15 Catalyst layer 16 Diffusion layer 17 Electrode (cathode, air electrode)
18 Separator 18A Cooling separator 18B Reactor gas separators 18a, 18b Metal plate 18c Intermediate metal plate 19 Module 20 Terminal 21 Insulator 22 End plate 23 Stack 24 Fastening member (tension plate)
25 Bolt or nut 26 Cooling water flow path 26a Front side cooling water flow path 26b of intermediate metal plate Back side cooling water flow path 27 of intermediate metal plate 27 Gas flow path 27a Fuel gas flow path 27b Oxidizing gas flow path 28 Cooling water manifold 29 Gas manifold 30 Hole 31 Frame 32 Gasket 33 (Tunnel-shaped) flow path 34 Laminated surface 35 Step

Claims (2)

In a fuel cell separator with a resin frame having a resin frame with a built-in manifold around the separator,
The separator is a metal separator, an outer edge portion of the separator extends into the resin frame and stops in front of a manifold formed in the resin frame, and the outer edge portion of the separator is embedded in the resin frame and It is molded integrally with the frame,
A tunnel-like flow path that connects the manifold and the inner space of the inner peripheral surface of the resin frame is formed on the inner peripheral portion of the resin frame from the manifold.
A fuel cell separator. 2. The fuel cell separator according to claim 1, wherein the flow path extends linearly over the entire length of the flow path, and the inner surface of the separator side portion of the flow path is flush with the surface of the separator.

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