KR20220090626A - Separator for fuel cell with improved sealability and apparatus and method for manufacturing same - Google Patents

Abstract

A separator for a fuel cell according to an embodiment of the present invention includes: a first separator member and a second separator member attached to a membrane electrode assembly including a first electrode and a second electrode; and a sealing member interposed between the first separator member and the second separator member, wherein a concave-convex portion in close contact with the sealing member may be formed on a bonding surface of the first separator member joined to the sealing member, and the sealing member and Concave-convex portions in close contact with the sealing member may be formed on the bonding surface of the second separator member to be joined.

Description

A separator for fuel cells with improved airtightness, an apparatus for manufacturing a separator for a fuel cell, and a method for manufacturing a separator for a fuel cell TECHNICAL FIELD

The present invention relates to a separator for a fuel cell, an apparatus for manufacturing a separator for a fuel cell, and a method for manufacturing a separator for a fuel cell.

In general, a fuel cell is a device that supplies hydrogen to an anode and oxygen to a cathode to obtain electrical energy through an electrochemical reaction between hydrogen and oxygen. Since fuel cells do not emit harmful gases and generate less noise and vibrations, they are in the spotlight as a next-generation energy source.

Fuel cells are classified into a polymer electrolyte fuel cell (PEMFC), a phosphoric acid fuel cell (PAFC), a molten carbonate fuel cell (MCFC), and a solid oxide fuel cell (SOFC) according to the type of electrolyte. Among these fuel cells, a polymer electrolyte fuel cell (PEMFC) is widely used.

A polymer electrolyte fuel cell has a structure in which tens to hundreds of unit cells are stacked in series. The unit cell is composed of a solid polymer electrolyte membrane, an electrode, and a separator.

The separator serves to separate hydrogen and oxygen supplied to the electrode. The separator needs to have a very high gas impermeability since it must completely separate hydrogen and oxygen. In addition, the separator needs to have excellent electrical conductivity since it must transmit electrical energy to the end plate, which is a current collector, without loss of power. In addition, since the separator occupies a large volume in the fuel cell, the separator needs to be manufactured to have a small thickness in order to reduce the weight of the fuel cell manufactured with a large capacity. In addition, the separator needs to have rigidity to withstand vibration and external force despite its small thickness.

In addition, the separator needs to have airtightness to prevent gas passing through a gas flow path formed therein from leaking to the outside.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a separator for a fuel cell with improved airtightness, an apparatus for manufacturing a separator for a fuel cell, and a method for manufacturing a separator for a fuel cell.

A separator for a fuel cell according to an embodiment of the present invention for achieving the above object includes a first separator member and a second separator member attached to a membrane electrode assembly including a first electrode and a second electrode; and a sealing member interposed between the first separator member and the second separator member, wherein a concave-convex portion in close contact with the sealing member may be formed on a bonding surface of the first separator member joined to the sealing member, and the sealing member and Concave-convex portions in close contact with the sealing member may be formed on the bonding surface of the second separator member to be joined.

In addition, an apparatus for manufacturing a separator for a fuel cell according to an embodiment of the present invention is for manufacturing a separator for a fuel cell including a first plate, a second plate, and a molding material interposed between the first plate and the second plate. , a first mold configured to mount the first plate and the second plate; a second mold disposed to face the first mold; a heating unit configured to heat the molding material; a plate supply unit configured to supply the first plate and the second plate between the first mold and the second mold; a molding material application unit for applying a molding material onto a first plate mounted on the first mold; and a concave-convex portion forming unit for forming concave-convex portions on the surface of any one of the first plate and the second plate.

In addition, the method for manufacturing a separator for a fuel cell according to an embodiment of the present invention is for manufacturing a separator for a fuel cell including a first plate, a second plate, and a molding material interposed between the first plate and the second plate. , mounting the first plate on the first mold; applying a molding material on a first plate mounted on a first mold; bonding the second plate onto the first plate to which the molding material is applied; heating the first plate, the second plate and the molding material while pressing to form a plate assembly; and forming an uneven portion on one surface of the plate assembly.

In the separator for a fuel cell according to an embodiment of the present invention, a first separator member and a second separator member constituting a pair of separators are joined to each other with a sealing member interposed therebetween, and bonding of the first separator member joined to the sealing member Concave-convex portions in close contact with the sealing member are formed on the surface, and concave-convex portions in close contact with the sealing member are formed on the bonding surface of the second separator member joined to the sealing member. Accordingly, the first separator member, the second separator member, and the sealing member can be firmly coupled to each other. Therefore, even if an external impact is applied, slip does not occur between the first separator member and the second separator member, and accordingly, the position of the first separator member and the position of the second separator member do not fluctuate. In addition, since the first separator member, the second separator member, and the sealing member are in close contact with each other, the effect of the sealing member for preventing leakage of the first gas, the second gas, or the refrigerant may be improved.

1 is a diagram schematically illustrating a separator for a fuel cell according to an embodiment of the present invention.
2 is a diagram schematically illustrating a configuration in which a separator for a fuel cell is coupled to a membrane electrode assembly according to an embodiment of the present invention.
3 to 7 are diagrams schematically illustrating an apparatus for manufacturing a separator for a fuel cell according to an embodiment of the present invention.

Hereinafter, a separator for a fuel cell and an apparatus for manufacturing the same according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1 , the separator 50 for a fuel cell according to an embodiment of the present invention may be manufactured using a mixture (hereinafter referred to as a molding material) in which a thermosetting resin, electrically conductive particles, and carbon fibers are mixed. have. For example, the separator 50 may be manufactured using a molding material prepared by mixing 20 to 35 wt.% of a thermosetting resin and 80 to 65 wt.% of electrically conductive particles and carbon fibers.

The thermosetting resin may be a phenolic resin. However, the present invention is not limited thereto, and various thermosetting resins may be used.

The electrically conductive particles may be carbon black particles. Since the carbon black particles have high electrical conductivity, the electrical conductivity of the separator 50 manufactured using the carbon black particles can be improved. In addition, since the carbon black particles have excellent processability, the separator 50 manufactured using the carbon black particles may have a thickness as small as 1 to 2 mm.

Meanwhile, as the amount of carbon black particles increases, the electrical conductivity of the separator 50 may improve, but the strength of the separator 50 may decrease. Therefore, in order to supplement the strength of the separator 50, the separator 50 is manufactured using a mixture of carbon black particles mixed with carbon fibers. For example, the carbon fiber may be any one of a PAN-based carbon fiber, a pitch-based carbon fiber, and a cellulose-based carbon fiber. For example, the carbon fiber may have a length of 1 to 12 mm, but the present invention is not limited to the length of the carbon fiber.

As shown in FIG. 1 , the separator 50 for a fuel cell according to the embodiment of the present invention includes a plurality of manifold holes 111 , 112 , 121 , 122 , 131 , 132 , a plurality of manifold protrusions 211 , 212 , 221 , 222 , 231 , 232 , a plurality of flow path ribs 300 , and a plurality of outer protrusions 411 and 421 are provided.

The plurality of manifold holes 111 , 112 , 121 , 122 , 131 and 132 includes a plurality of gas manifold holes 111 , 112 , 121 , 122 and a pair of refrigerant manifold holes 131 and 132 . do.

The plurality of gas manifold holes 111 , 112 , 121 , and 122 include a pair of first gas manifold holes 111 and 112 and a pair of second gas manifold holes 121 and 122 .

The pair of first gas manifold holes 111 and 112 include a first gas inlet hole 111 through which the first gas is introduced, and a first gas outlet hole 112 through which the first gas is discharged. The first gas flows into the separator 50 through the first gas inlet hole 111 , passes through the first gas flow path inside the separator 50 , and then through the first gas outlet hole 112 to the separator (50) is discharged to the outside.

The pair of second gas manifold holes 121 and 122 include a second gas inlet hole 121 through which a second gas is introduced, and a second gas outlet hole 122 through which the second gas is discharged. The second gas is introduced into the separator 50 through the second gas inlet hole 121 , passes through the second gas flow path inside the separator 50 , and then through the second gas outlet hole 122 to the separator. (50) is discharged to the outside.

Here, any one of the first gas and the second gas may be a fuel gas, and the other of the first gas and the second gas may be an oxidizing gas.

Each of the manifold protrusions 211 , 212 , 221 , 222 , 231 , and 232 may extend along the circumference of each of the manifold holes 111 , 112 , 121 , 122 , 131 and 132 . Each of the manifold protrusions 211 , 212 , 221 , 222 , 231 , and 232 is formed to surround each of the manifold holes 111 , 112 , 121 , 122 , 131 and 132 . Each of the manifold protrusions 211, 212, 221, 222, 231, 232 protrudes from the surface of the separator 50 and flows through the manifold holes 111, 112, 121, 122, 131, and 132; It serves to prevent the first gas or the second gas from leaking to the outside.

The plurality of outer protrusions 411 and 421 may extend along the outer edge of the separator 50 . The plurality of outer protrusions 411 and 421 include a first outer protrusion 411 and a second outer protrusion 421 .

The first outer protrusion 411 is formed to surround the plurality of flow path ribs 300 . The second outer protrusion 421 includes a plurality of flow path ribs 300 , a plurality of manifold holes 111 , 112 , 121 , 122 , 131 , 132 , and a plurality of manifold protrusions 211 , 212 , 221 , 222 , 231 . , 232). The plurality of outer protrusions 411 and 421 serves to prevent the refrigerant, the first gas, or the second gas flowing in the separator 50 from leaking to the outside.

The plurality of flow path ribs 300 may protrude from the surface of the separator 50 . The plurality of flow path ribs 300 may be formed to be spaced apart from each other. Accordingly, a first gas flow path through which the first gas passes or a second gas flow path through which the second gas passes is formed between the plurality of flow path ribs 300 . can be formed.

According to an embodiment of the present invention, a pair of separators 50 may be coupled to each other to constitute one assembly. When the pair of separators 50 are coupled to each other, the plurality of manifold protrusions 211 , 212 , 221 , 222 , 231 , 232 of one separator 50 becomes a plurality of the plurality of separators 50 of the other separator 50 . It may be bonded to the manifold protrusions 211 , 212 , 221 , 222 , 231 , and 232 . At this time, the bonding surface of the plurality of manifold protrusions 211 , 212 , 221 , 222 , 231 , 232 of one separator 50 and the plurality of manifold protrusions 211 , 212 of the other separator 50 , The bonding surfaces of 221 , 222 , 231 , and 232 may be in contact with each other.

In addition, when the pair of separators 50 are coupled to each other, the plurality of outer protrusions 411 and 421 of one separator 50 are replaced with the plurality of outer protrusions 411 and 421 of the other separator 50 . can be joined to In this case, the bonding surface of the plurality of outer protrusions 411 and 421 of one separator 50 and the bonding surface of the plurality of outer protrusions 411 and 421 of the other separator 50 may be in contact with each other.

As shown in FIG. 2 , the separator 50 is formed of a plate-shaped member bent at regular intervals. The separator 50 may include a first plate 501 , a second plate 502 , and a molding material 503 interposed between the first plate 501 and the second plate 502 .

The first plate 501 and the second plate 502 may be formed of a material having electrical conductivity. For example, the first plate 501 and the second plate 502 may be formed of metal.

Since the separator 50 includes the first plate 501 and the second plate 502 , the rigidity of the separator 50 may be improved compared to the case in which the separator 50 is configured as a single plate. It is possible to enable the separator 50 to withstand vibration and external force despite its small thickness.

In addition, since the first plate 501 and the second plate 502 constitute both surfaces of the separator 50 , electrical conductivity on the surface of the separator 50 can be improved.

The molding material 503 may include a thermosetting resin such as a phenolic resin. As the thermosetting resin is cured by heat, the first plate 501 and the second plate 502 may be bonded to each other.

The molding material 503 may include a reinforcing material such as carbon fiber, glass fiber, or the like. As the molding material 503 includes the reinforcing material, the rigidity of the separator 50 may be improved.

The molding material 503 may include electrically conductive particles, such as metal particles. The electrically conductive particles may include metal particles, graphite particles, carbon nanotubes, carbon black particles, or a combination thereof. As the molding material 503 includes electrically conductive particles, the electrical conductivity of the separator 50 may be improved.

As shown in FIG. 2 , a pair of separators 50 are coupled to the membrane electrode assembly 60 to form one unit cell. Then, a plurality of unit cells are stacked to form a fuel cell stack.

The membrane electrode assembly 60 includes a first electrode 61 , a second electrode 62 , and an electrolyte membrane 63 . The electrolyte membrane 63 is disposed between the first electrode 61 and the second electrode 62 .

A gas diffusion layer 64 may be disposed between the membrane electrode assembly 60 and the separator 50 .

Any one of the first electrode 61 and the second electrode 62 may be an anode, and the other one of the first electrode 61 and the second electrode 62 may be a cathode.

The space between the plurality of flow path ribs 300 is sealed by the pair of separators 50 being coupled to the first electrode 61 and the second electrode 62 , and accordingly, the plurality of flow path ribs 300 . A first gas flow path and a second gas flow path may be formed in a longitudinal direction of .

The pair of separators 50 includes a first separator member 51 disposed adjacent to the first electrode 61 and a second separator member 52 disposed adjacent to the second electrode 62 . .

When the first separator member 51 is coupled to the first electrode 61 , a first gas flow path 310 may be formed between the first separator member 51 and the first electrode 61 . The first gas may flow along the first gas flow path 310 .

When the second separator member 52 is coupled to the second electrode 62 , a second gas flow path 320 may be formed between the second separator member 52 and the second electrode 62 . The second gas may flow along the second gas flow path 320 .

Also, when the first separator member 51 and the second separator member 52 are coupled to each other, a refrigerant flow path 330 may be formed between the first separator member 51 and the second separator member 52 . have. The refrigerant may flow along the refrigerant passage 330 .

A sealing member 70 may be interposed between the first separator member 51 and the second separator member 52 . The sealing member 70 may be formed of rubber or synthetic resin. The sealing member 70 serves to prevent leakage of the first gas, the second gas, or the refrigerant between the first separator member 51 and the second separator member 52 to the outside. Accordingly, it is possible to prevent a decrease in the electricity production efficiency of the fuel cell due to leakage of the refrigerant, the first gas, or the second gas.

The first separator member 51 has a bonding surface bonded to the second separator member 52 , and the second separator member 52 has a bonding surface bonded to the first separator member 51 . Then, the sealing member 70 is interposed between the bonding surface of the first separator member 51 and the bonding surface of the second separator member 52 .

Concave-convex portions 59 may be formed on the bonding surface of the first separator member 51 . For example, an uneven portion 59 may be formed on one surface of the first plate 501 and the second plate 502 of the first separator member 51 (see FIG. 2 , the second plate 502 ). ) in which the concave-convex portion 59 is formed is shown).

In addition, concavo-convex portions 59 may be formed on the bonding surface of the second separator member 52 . For example, an uneven portion 59 may be formed on one surface of the first plate 501 and the second plate 502 of the second separator member 52 (see the second plate 502 in FIG. 2 ). ) in which the concave-convex portion 59 is formed is shown).

In this way, the first separator member 51 and the second separator member 52 each include a first plate 501 and a second plate 502 constituting both surfaces thereof. In addition, the first plate 501 and the second plate 502 are formed of a metal material having a predetermined rigidity. Accordingly, the shapes of the concavo-convex portions 59 formed in the metal material of the first plate 501 and the second plate 502 can be constantly maintained.

Since the uneven portion 59 is formed on the bonding surface of the first separator member 51 , the contact area (contact force) between the first separator member 51 and the sealing member 70 may be improved. In addition, since the uneven portion 59 is formed on the bonding surface of the second separator member 52 , the contact area (contact force) between the second separator member 52 and the sealing member 70 can be improved.

Accordingly, the first separator member 51 , the second separator member 52 , and the sealing member 70 may be firmly coupled to each other. Therefore, even if an external impact is applied, slip does not occur between the first separator member 51 and the second separator member 52, and accordingly, the position of the first separator member 51 and the second separator member 52 ) does not change its position.

In addition, the concavo-convex portion 59 of the first separator member 51 closely adheres to the sealing member 70 , and the concavo-convex portion 59 of the second separator member 52 closely adheres to the sealing member 70 . Therefore, the effect of the sealing member 70 for preventing leakage of the first gas, the second gas, or the refrigerant may be improved.

3 to 7 , the separator manufacturing apparatus 80 for manufacturing the separator 50 includes a first mold 81 , a second mold 82 , a heating unit 83 , and a drive unit 84 . ), a plate supply unit 85 , a molding material application unit 86 , and an uneven portion forming unit 87 .

The first mold 81 and the second mold 82 are arranged to face each other.

A first plate 501 and a second plate 502 may be mounted on the first mold 81 .

A plurality of protrusions and a plurality of grooves may be formed in the first mold 81 and the second mold 82 . When the first mold 81 and the second mold 82 press the first plate 501 and the second plate 502 , a plurality of projections of the first mold 81 and the second mold 82 and A plurality of grooves press the first plate 501 and the second plate 502, and accordingly, a plurality of manifold holes 111, 112, 121, 122, 131, 132, a plurality of manifold protrusions 211 , 212 , 221 , 222 , 231 , 232 ), a plurality of flow path ribs 300 , and a separator 50 having a plurality of outer protrusions 411 and 421 may be formed.

The heating unit 83 may be installed in the first mold 81 . However, the present invention is not limited to the installation position of the heating unit 83 , and the present invention may also be applied to a configuration in which the heating unit 83 is installed in the second mold 82 .

The heating unit 83 serves to heat and harden the molding material 503 interposed between the first plate 501 and the second plate 502 mounted on the first mold 81 .

The driving unit 84 may be connected to the second mold 82 to move the second mold 82 with respect to the first mold 81 . As the second mold 82 is moved toward the first mold 81 by the driving unit 84 , the first plate 501 and the second plate 502 are moved by the first mold 81 and the second mold 81 . (82) can be pressed between. With the molding material 503 interposed between the first plate 501 and the second plate 502 , the first plate 501 and the second As the plate 502 is pressed, the plate assembly 53 may be completed.

The plate supply unit 85 is configured to supply the first plate 501 and the second plate 502 between the first mold 81 and the second mold 82 .

The plate supply unit 85 may include a clamp 851 and a clamp movement module 852 . The clamp 851 may be configured to grip the first plate 501 and the second plate 502 . The clamp movement module 852 may be configured to horizontally move the clamp 851 .

The molding material application unit 86 is configured to apply the molding material 503 on the first plate 501 mounted on the first mold 81 . The molding material application unit 86 may be configured as a nozzle movable along the upper surface of the first mold 81 .

The concave-convex portion forming unit 87 is configured to form the concave-convex portion 59 on the surface of the separator 50 . The concave-convex part forming unit 87 includes a conveying unit 871 which conveys the plate assembly 53, and one surface (one side of the second plate 502) of the plate assembly 53 conveyed by the conveying unit 871. It may include an uneven portion forming roller 872 that forms the portion 59 .

The transfer unit 871 may be implemented in various configurations capable of transferring the plate material, such as rollers and conveyor belts.

The uneven portion forming roller 872 may be a knurling roller for forming the uneven portion 59 on one surface of the plate assembly 53 . A plurality of projections and a plurality of grooves may be formed on the surface of the uneven portion forming roller 872 in a shape corresponding to the uneven portion 59 .

Hereinafter, with reference to FIGS. 3-7, the method of manufacturing the separator 50 for fuel cells using the separator manufacturing apparatus 80 is demonstrated.

First, as shown in FIG. 3 , the first plate 501 is supplied between the first mold 81 and the second mold 82 by the plate supply unit 85 . The first plate 501 supplied between the first mold 81 and the second mold 82 may be mounted on the upper surface of the first mold 81 .

Then, as shown in FIG. 4 , a molding material 503 is applied on the first plate 501 mounted on the first mold 81 by the molding material application unit 86 .

Then, as shown in FIG. 5 , the second plate 502 is supplied between the first mold 81 and the second mold 82 by the plate supply unit 85 . The second plate 502 supplied between the first mold 81 and the second mold 82 may be bonded to the first plate 501 .

And, as shown in FIG. 6 , as the second mold 82 is moved toward the first mold 81 by the driving unit 84 , the first plate 501 and the second plate 502 are It may be pressed between the first mold 81 and the second mold 82 .

In this process, as the heating unit 83 emits heat, the molding material 503 interposed between the first plate 501 and the second plate 502 is heated and hardened.

In this way, in a state in which the molding material 503 is interposed between the first plate 501 and the second plate 502 , the first plate 501 is formed by the first mold 81 and the second mold 82 . , as the second plate 502 and the molding material 503 are pressed and heated, the plate assembly 53 may be completed.

And, as shown in FIG. 7 , the plate assembly 53 is transferred toward the uneven portion forming roller 872 by the transfer unit 871 of the uneven portion forming unit 87 .

Then, while the plate assembly 53 is transferred by the transfer unit 871 , the uneven portion forming roller 872 presses one surface of the plate assembly 53 . Accordingly, the separator 50 in which the uneven portions 59 are formed on one surface may be completed.

In addition, in the separator 50 for a fuel cell according to the embodiment of the present invention, the first separator member 51 and the second separator member 52 constituting the pair of separators 50 are provided with a sealing member 70 interposed therebetween. A concave-convex portion 59 in close contact with the sealing member 70 is formed on the bonding surface of the first separator member 51 which is bonded to each other and bonded to the sealing member 70 , and is joined to the sealing member 70 . A concave-convex portion 59 in close contact with the sealing member 70 is formed on the bonding surface of the second separator member 52 . Accordingly, the first separator member 51 , the second separator member 52 , and the sealing member 70 may be firmly coupled to each other. Therefore, even if an external impact is applied, slip does not occur between the first separator member 51 and the second separator member 52, and accordingly, the position of the first separator member 51 and the second separator member 52 ) does not change its position. In addition, since the first separator member 51 , the second separator member 52 , and the sealing member 70 are in close contact with each other, the sealing member 70 prevents leakage of the first gas, the second gas, or the refrigerant. The effect can be improved.

The separator 50 for a fuel cell according to an embodiment of the present invention includes a first plate 501 having electrical conductivity, a second plate 502 having electrical conductivity, and a first plate 501 and a second plate 502 . ) and is composed of a molding material 503 including a thermosetting resin, a reinforcing material, and electrically conductive particles. In addition, the separator manufacturing apparatus 80 for a fuel cell according to the embodiment of the present invention includes a first plate 501 with a molding material 503 interposed between the first plate 501 and the second plate 502 . , the second plate 502 and the molding material 503 are heated and pressurized to manufacture the fuel cell separator 50 . Accordingly, the rigidity and electrical conductivity of the separator 50 for a fuel cell may be improved.

Although preferred embodiments of the present invention have been described by way of example, the scope of the present invention is not limited to such specific embodiments, and may be appropriately modified within the scope described in the claims.

50: separator
60: membrane electrode assembly
80: separator manufacturing device

Claims (3)

a first separator member and a second separator member attached to a membrane electrode assembly including a first electrode and a second electrode; and
a sealing member interposed between the first separator member and the second separator member;
A concave-convex portion in close contact with the sealing member is formed on a bonding surface of the first separator member bonded to the sealing member;
A fuel cell separator, wherein a concave-convex portion in close contact with the sealing member is formed on a joint surface of the second separator member joined to the sealing member. An apparatus for manufacturing a separator for a fuel cell comprising a first plate, a second plate, and a molding material interposed between the first plate and the second plate,
a first mold configured to mount the first plate and the second plate;
a second mold disposed to face the first mold;
a heating unit configured to heat the molding material;
a plate supply unit configured to supply the first plate and the second plate between the first mold and the second mold;
a molding material application unit for applying the molding material onto the first plate mounted on the first mold; and
and a concavo-convex portion forming unit for forming concavo-convex portions on a surface of any one of the first plate and the second plate. A method for manufacturing a separator for a fuel cell comprising a first plate, a second plate, and a molding material interposed between the first plate and the second plate, the method comprising:
mounting the first plate on a first mold;
applying the molding material on the first plate mounted on the first mold;
bonding the second plate to the first plate to which the molding material is applied;
forming a plate assembly by heating the first plate, the second plate, and the molding material while pressing; and
and forming an uneven portion on one surface of the plate assembly.

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