JP2005285712A - Gasket for fuel cell - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a gasket for a fuel cell having excellent shape stability and capable of stabilizing operation property when mounting it. <P>SOLUTION: A lip part 2 is provided on a surface, and a channel part 3 is provided on a rear surface. Adhesive 5 is applied to the channel part 3 and is hardened in a pressing condition in which the lip part 2 is crushed at a fixing position of a separator 7 to bond on the separator 7. Two seal bearing pressure peak sections 10 are formed in the lip part 2. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a fuel cell gasket used in a fuel cell.

  In a fuel cell stack having a structure in which an MEA (polymer electrolyte membrane carrying a catalyst electrode layer) is sandwiched between grooved fuel cell separators and stacked in layers, the MEA and the separator (circulation of fuel gas and air) Part) and between the separators of the cooling water circulating part and the separators are required to be sealed, and a gasket made of a rubber elastic body is generally mounted at the sealing position.

  This gasket is used by being integrally fixed to the MEA or the separator in consideration of the assembling property of the fuel cell stack. As the integration method, a method of directly molding on the substrate such as the MEA or separator, A method in which a pre-formed gasket is pasted with an adhesive is widely used.

  Of these methods, the method of post-pasting the molded gasket on the separator (see Patent Document 1) eliminates the need to apply excessive molding pressure to the separator when molding the gasket directly on the separator. It is suitably used in brittle carbon separators and thin metal separators.

  However, in recent years, due to the high demand for downsizing of the fuel cell stack, further reduction in the thickness of the separator and reduction in the distance between the MEA and the separator are progressing. For this reason, even when using the gasket post-bonding integration method, it has been required to reduce the thickness of the base and lip of the gasket, resulting in a problem that the operability when the gasket is bonded to the separator becomes complicated. It was.

  That is, with the thinning of a generally gasket-like gasket, for example, the gasket may be twisted, entangled, broken, etc., making it difficult to maintain the shape of the gasket itself, and causing problems in mounting at a predetermined fixing position. Becomes prominent.

  Regarding the thinning of the lip part of the gasket, the purpose is to suppress the breakage and deformation of the separator that causes a sealing failure due to the seal surface pressure of the gasket in the brittle resin binder type carbon separator or thin metal separator. It is also performed as a means for reducing the reaction force of the lip portion.

  As a prior example of the gasket post-pasting, there is also the one described in Patent Document 2, but in this case, a gasket molded into a resin sheet is post-pasted and has excellent shape stability (operability). However, the thickness reduction of the resin sheet is impaired, and the resin sheet that can withstand the molding of the gasket has a problem that the material is expensive.

Further, in the gasket for a fuel cell, a material having a lower reaction force and an excellent sealing property is required for the convenience of the separator component, and examples thereof include those described in Patent Document 2 and Patent Document 3. As shown in FIG. 3, there is a method in which a plurality of minute protrusions are provided on the lip portion of the gasket, and sealing is performed in multiple stages at a plurality of low surface pressure portions. However, such a lip shape has a problem that the molding process such as dimensional accuracy becomes complicated.
JP 2002-33109 A JP 2003-56704 A JP 2000-133288 A

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a fuel cell gasket having excellent shape stability and stable operability during mounting.

  To achieve the above object, the fuel cell gasket according to the present invention is provided with a lip portion on the front surface and a groove portion on the back surface, an adhesive is applied to the groove portion, and the lip portion is fixed to the fuel cell separator. The adhesive is cured in a pressed state in which the portion is crushed, and is adhered onto the fuel cell separator, and a plurality of seal surface pressure peaks are formed on the lip portion.

  According to the present invention, the fuel cell gasket is excellent in shape stability, twisted and entangled, is not broken, and the operability during mounting is improved.

  Further, since a plurality of seal surface pressure peaks are formed in the lip portion, it is possible to perform multi-stage sealing with a low seal surface pressure.

  Furthermore, since the adhesive is applied in the groove portion, the required amount of the adhesive can be ensured uniformly, and a strong and continuous adhesion can be obtained without unevenness. .

  The embodiment will be described with reference to FIGS. 1 and 2. FIG. 1 is a single sectional view of a fuel cell gasket according to an embodiment before bonding. FIG. 2 is a process diagram showing a process of attaching the fuel cell gasket to the fuel cell separator according to the embodiment.

  The fuel cell gasket 1 seals between the MEA and the fuel cell separator (a circulation part of fuel gas and air) and between the separator and the separator in the cooling water circulation part in the fuel cell stack, as in the past.

  A single body before bonding of the gasket 1 according to the embodiment will be described with reference to FIG.

  The gasket 1 shown in FIG. 1 is formed in advance and is used by a method of pasting with an adhesive 5. The gasket 1 has a strip-shaped base 4, a lip portion 2 having a substantially rectangular cross section is formed at the center of the front surface of the base portion 4, and a groove portion 3 is formed at the center of the back surface, that is, directly behind the lip portion 2. In other words, the gasket 1 has a lip portion 2 with a groove 3 formed on the back, and a base 4 provided outside the lip portion 2.

  In the present embodiment, the base 4 is provided in the gasket 1, but the base 4 may not be provided, and depends on the shape of the gasket to be manufactured.

  If the wall thickness including the lip portion 2 of the gasket 1 is too thick, it is difficult to obtain a desired surface pressure distribution. Therefore, the thickness is about 0.2 to 2 mm, preferably about 0.3 to 1 mm. However, since the gasket 1 having a wall thickness of about 1 mm or more does not cause much trouble in operability, the wall thickness at which the effect of the present invention is further exhibited is about 0.3 to 0.6 mm.

  Further, if the width dimension of the lip portion 2 is too narrow, it becomes difficult to mold the gasket 1, and even if it is larger than necessary, the space is wasted, so it is set to about 1 to 3 mm.

  The size of the base portion 4 is not particularly limited, and when the gasket 1 is mounted in the mounting groove 8 of the fuel cell separator 7, it is provided within about 1 mm on both sides of the lip portion 2. There is no particular problem even if the shape covers the region requiring insulation.

  The groove part 3 has a substantially semicircular cross section so that the seal surface pressure distribution of the gasket 1 after mounting changes continuously. The size of the groove portion 3 is a range narrower than the width of the substantially rectangular lip portion, and is a maximum depth of 10 to 50%, preferably 20 to 30% of the lip portion height. Moreover, although the groove part 3 is mentioned later, in order to provide two seal | sticker surface peaks, the deepest part is substantially match | combined and provided in the center of the width direction of the lip | rip part 2. FIG. In addition, although the groove surface 3 can increase the seal surface pressure peak by providing a plurality of locations, even if the distribution of the seal surface pressure is changed very finely, the sealing performance is not affected. One location is preferred.

  The material of the gasket 1 may be any material usually used for gaskets, such as silicone, fluororubber, EPDM, nitrile rubber, etc., but the hardness is preferably (JIS A) 60 or less.

  The mounting process of the gasket 1 according to the embodiment will be described with reference to FIG.

  (1) First, the adhesive 5 is applied in the groove 3 having a semicircular cross section on the back of the gasket 1 (FIG. 2A). Since the adhesive 5 is applied to the groove 3 having a certain depth, it can be held in the groove 3 without protruding a necessary amount. That is, the groove portion 3 is an adhesive reservoir for holding a necessary amount of the adhesive 5.

  (2) The gasket 1 in which the adhesive 5 is applied to the groove 3 on the back surface is disposed on the separator 7, and the adhesive 5 is cured by being pressed from the surface of the gasket 1 with the fixing mold 6 and heated. The gasket 1 is attached to 7 (FIG. 2B).

  A mounting groove 8 in which the gasket 1 is mounted is formed in the separator 7, and the gasket 1 is disposed in this (fixed position) with the back surface in contact with the fuel cell separator 7. The separator 7 may have a planar shape without the mounting groove 8.

  And it presses with the type | mold 6 for fixing from the gasket 1 surface side, and also heats in the press state which crushed the lip | rip part 2, and the adhesive agent 5 is hardened. In the pressing state of the gasket 1, the lip portion 2 comes into contact with the fixing die 6 and is crushed and pressed flat, and the groove portion 3 is also pressed against the separator 7 to form a shallow adhesive curing portion 9.

  (3) Remove the fixing die 6 to obtain the gasket 1 attached to the separator 7 (FIG. 2 (c)).

  In the gasket 1 in the mounted state, the lip portion 2 is crushed and deformed by the adhesion in the pressing state in the previous step, and the protruding portions 10 as two seal surface pressure peak portions are formed on the lip portion 2. Further, the groove portion 3 also becomes a shallow and shallow adhesive curing portion 9, and a sufficiently strong adhesion is performed with a necessary amount of the adhesive 5.

  Thus, the gasket 1 is attached to the separator 7. Further, the gasket shape can be changed simultaneously with the mounting so that the gasket 1 can have a low reaction force and an excellent sealing property.

  According to the above embodiment, the gasket 1 has excellent shape stability, is not twisted, entangled, is not broken, and has an operation at the time of mounting on the separator 7 as compared with the conventional gasket shape that can obtain the same seal surface pressure. Improves.

  Further, since two protrusions 10 which are seal surface pressure peak portions are formed on the lip portion 2, it can be sealed in multiple stages with a low seal surface pressure, and can have a low reaction force and excellent sealing performance. In addition, since the shape in which the two protruding portions 10 are formed on the lip portion 2 is performed only by pressing the fixing die 6 when the gasket 1 is attached to the separator 7 (at the time of bonding), the manufacturing is easy. There is no need for molding that complicates dimensional accuracy.

  Furthermore, since the adhesive 5 is applied in the groove portion 3, the required amount of the adhesive 5 can be ensured uniformly, and a strong and continuous adhesion can be obtained. In this case, there is no failure (seal failure due to poor adhesion) that results in insufficient adhesion due to uneven adhesion, and the sealing property is also improved.

  The present invention is used not only for fuel cells but also for gaskets such as HDD covers.

It is a single sectional view before adhesion of the gasket for fuel cells concerning an embodiment. It is process drawing which shows the mounting process to the fuel cell separator of the fuel cell gasket which concerns on embodiment. It is sectional drawing of the gasket for fuel cells of a prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Fuel cell gasket 2 Lip part 3 Groove part 4 Base part 5 Adhesive 6 Fixing type | mold 7 Fuel cell separator 8 Mounting groove 9 Adhesive hardening part 10 Protrusion part (seal surface pressure peak location)

Claims (1)

A lip portion is provided on the front surface, a groove portion is provided on the back surface, an adhesive is applied to the groove portion, and the adhesive is cured in a pressed state in which the lip portion is crushed at a fixed position of the fuel cell separator. A gasket for a fuel cell, wherein the gasket is bonded and a plurality of seal surface pressure peaks are formed on the lip portion.

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