KR102529914B1 - Unit cell for fuel cell - Google Patents

Abstract

The present invention relates to a unit cell for a fuel cell, comprising: a membrane-electrode assembly; a microporous layer disposed on one side of the membrane-electrode assembly; a conductor plate having electrical conductivity higher than that of the microporous layer and disposed on one surface of the microporous layer to be electrically connected to the microporous layer; and land parts and channel parts alternately formed along a predetermined direction, wherein the land parts are electrically connected to the conductor plate and the channel parts form a reactive gas passage for transporting the reactive gas. and a separating plate disposed on one side of the conductor plate.

Description

Unit cell for fuel cell {UNIT CELL FOR FUEL CELL}

The present invention relates to a unit cell for a fuel cell.

A fuel cell stack, as a main power supply source of a fuel cell vehicle, is a device that generates electricity through an oxidation-reduction reaction between hydrogen and oxygen.

In general, a fuel cell stack includes a membrane-electrode assembly (MEA), gas diffusion layers (GDL) disposed on both sides of the membrane-electrode assembly, and microporous layers disposed on the gas diffusion layers, respectively. , a plurality of unit cells including separators, etc. are stacked and configured.

The membrane-electrode assembly includes a polymer electrolyte membrane, an anode electrode disposed on one surface of the polymer electrolyte membrane, and a cathode electrode disposed on the other surface of the polymer electrolyte membrane. The separator includes a hydrogen channel for supplying hydrogen to the anode electrode, an air channel for supplying air to the cathode electrode, and a cooling water channel for flowing cooling water.

High-purity hydrogen supplied from the hydrogen storage tank flows into the anode electrode through the hydrogen channel of the separator, and atmospheric air supplied by an air compressor or other air supply device flows through the air channel of the separator into the cathode electrode. Then, the oxidation reaction of hydrogen proceeds at the anode electrode to generate hydrogen ions (Proton) and electrons (Proton), and the generated hydrogen ions and electrons are moved to the cathode electrode through the polymer electrolyte membrane and the separator, respectively. In addition, in the cathode electrode, a reduction reaction involving hydrogen ions and electrons transferred from the anode electrode and oxygen in the air supplied by the air supply device proceeds to produce water, and at the same time, electric energy is generated by the flow of electrons.

Meanwhile, in recent years, in order to reduce the size of a unit cell, a cell developed by removing a gas diffusion layer to perform a role of a microporous layer (MPL) and a metal porous body together as a gas diffusion layer has been used.

The microporous layer is composed of a carbon support having a smaller thickness and smaller pores than a gas diffusion layer used in a conventional unit cell, and is interposed between the electrode and the separator. The electrons transferred to the microporous layer are diffused while moving in the surface direction of the microporous layer so that they can be uniformly distributed inside the microporous layer, and then transferred to other members electrically connected to the microporous layer. Due to this, the electrons transferred to the microporous layer are moved in the surface direction of the microporous layer by a significantly longer distance than the thickness of the microporous layer. Therefore, the conventional unit cell to which the microporous layer is applied has a problem in that the electrical resistance of the unit cell increases due to the movement of electrons in the surface direction of the microporous layer.

The metal porous body is composed of a metal foam formed by foaming a metal material, and is interposed between the microporous layer and the separator plate. Such a metal porous body has a high porosity by combining metal wires to form a mesh during the process of foaming the metal material. For this reason, the contact area between the porous metal body and the microporous layer is significantly narrower than the area of the porous metal body or the microporous layer. When electrons are transferred from the metal porous body to the microporous layer, the electrons are concentrated and transferred to a partial region of the microporous layer. Then, electrons transferred to the microporous layer are moved in the surface direction of the microporous layer by a significantly longer distance than the thickness of the microporous layer so as to be uniformly distributed inside the microporous layer. Therefore, the conventional unit cell to which the porous metal body is applied has a problem in that electrical resistance of the unit cell is increased due to the narrow contact area between the porous metal body and the microporous layer.

SUMMARY OF THE INVENTION The present invention is to solve the problems of the prior art described above, and an object of the present invention is to provide a unit cell for a fuel cell having an improved structure so as to reduce electrical resistance of the unit cell.

Furthermore, an object of the present invention is to provide a unit cell for a fuel cell having an improved structure to prevent damage to the microporous layer and the membrane-electrode assembly by the porous metal body.

A unit cell for a fuel cell according to a preferred embodiment of the present invention includes a membrane-electrode assembly; a microporous layer disposed on one side of the membrane-electrode assembly; a conductor plate having electrical conductivity higher than that of the microporous layer and disposed on one surface of the microporous layer to be electrically connected to the microporous layer; and land parts and channel parts alternately formed along a predetermined direction, wherein the land parts are electrically connected to the conductor plate and the channel parts form a reactive gas passage for transporting the reactive gas. and a separating plate disposed on one side of the conductor plate.

Preferably, the conductor plate is interposed between conductive parts respectively interposed between any one of the land parts and the one surface of the microporous layer, and between any one of the channel parts and the one surface of the microporous layer, respectively, , It is provided with passage parts provided so that the reaction gas can pass through.

Preferably, at least one of the flow passage portions communicates a connection wire formed to electrically connect at least one of the conductive portions and the microporous layer, and any one of the channel portions to the pores of the microporous layer. It has a flow hole formed.

Preferably, at least one of the passage parts is configured to communicate a connection rib formed to electrically connect at least one of the conductive parts and the microporous layer, and any one of the channel parts to the pores of the microporous layer. It has a first flow hole formed.

Preferably, at least one of the passage parts has a second passage hole formed in the connection rib so that any one of the channel parts communicates with the pores of the microporous layer.

Preferably, the microporous layer is composed of a gas diffusion layer or a carbon fiber layer in which a carbon support is impregnated with carbon fibers, and the conductor plate is composed of a metal material having higher electrical conductivity than the microporous layer.

A unit cell for a fuel cell according to another preferred embodiment of the present invention for solving the above problems is a membrane-electrode assembly; a microporous layer disposed on one side of the membrane-electrode assembly; a conductor plate having electrical conductivity higher than that of the microporous layer and disposed on one surface of the microporous layer to be electrically connected to the microporous layer; a porous metal body electrically connected to the conductor plate and disposed on one surface of the conductor plate to form a reaction gas passage for transporting a reaction gas; and a first separator disposed on one surface of the porous metal body to be electrically connected to the porous metal body.

Preferably, the conductor plate includes passage holes connecting pores of the metal porous body and pores of the microporous layer.

Preferably, the passage holes are formed such that the porosity of the conductor plate is lower than that of the metal porous body.

Preferably, the metal porous body is composed of a metal foam formed by foaming a metal material so that the metal wires are coupled in a mesh shape, and the passage holes have a diameter smaller than that of the metal wires.

Preferably, the membrane-electrode assembly includes land portions and channel portions alternately formed along a predetermined direction, and the land portions provide surface pressure to the membrane-electrode assembly in a thickness direction of the membrane-electrode assembly. It further includes a second separator disposed on the other side of the.

Preferably, the conductor plate includes first flow holes each formed in a first region of the conductor plate positioned on the same line as one of the land portions based on the thickness direction, and Second passage holes are respectively formed in the second region of the conductor plate positioned on the same line as one of the channel parts.

Preferably, the first passage holes and the second passage holes are formed such that the porosity of the first region is lower than that of the second region.

Preferably, the first passage holes have a smaller diameter than the second passage holes.

Preferably, the metal porous body is composed of a metal foam formed by foaming a metal material so that metal wires are coupled in a mesh shape, and the first passage holes have a diameter smaller than that of the metal wires.

Preferably, the conductor plate includes first meshes each formed in a first region of the conductor plate positioned on the same line as one of the land portions based on the thickness direction, and the first meshes based on the thickness direction. Second meshes are respectively formed in the second region of the conductor plate positioned on the same line as one of the channel parts.

Preferably, each of the first meshes is formed such that the porosity of the first region is lower than that of the second region.

Preferably, the microporous layer is composed of a carbon fiber layer, and the conductor plate is composed of a metal material having higher electrical conductivity than the microporous layer.

The present invention relates to a unit cell for a fuel cell, and has the following effects.

First, the present invention is a microporous conductor plate having a higher electrical conductivity than the microporous layer so that the electrons transferred to the microporous layer can reduce the distance that moves in the direction of the surface of the microporous layer. By laminating in layers, the electrical resistance of the unit cells can be reduced.

Second, the present invention can prevent the microporous layer and the membrane-electrode assembly from being damaged by the metal wires by using a conductor plate to block the metal wires constituting the metal porous body from reaching the microporous layer. can

1 is a cross-sectional view illustrating a stacked structure of a unit cell for a fuel cell according to a preferred embodiment of the present invention.
2 to 5 are plan views of a first conductor plate;
6 is a view showing how electrons and reactive gases are transferred through a first conductor plate;
7 to 9 are plan views of the second conductor plate;
10 is a diagram showing how electrons and reactive gases are transferred through a second conductor plate;

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing an embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function hinders understanding of the embodiment of the present invention, the detailed description will be omitted.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the nature, order, or order of the corresponding component is not limited by the term. In addition, unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the present application, they should not be interpreted in an ideal or excessively formal meaning. don't

1 is a cross-sectional view illustrating a stacked structure of a unit cell for a fuel cell according to a preferred embodiment of the present invention.

Referring to FIG. 1 , a fuel cell unit cell 1 (hereinafter referred to as 'unit cell 1') according to a preferred embodiment of the present invention includes a membrane-electrode assembly 10 and a membrane-electrode assembly ( 10), the first microporous layer 20 disposed on one surface, the second microporous layer 30 disposed on the other surface of the membrane-electrode assembly 10, and one surface of the first microporous layer 20. A first conductor plate 40 disposed thereon, a first separation plate 50 disposed on one surface of the first conductor plate 40, and a second conductor plate disposed on one surface of the second microporous layer 30 ( 60), the porous metal body 70 disposed on one surface of the second conductor plate 60, and the second separator 80 disposed on one surface of the porous metal body 70.

First, the membrane-electrode assembly 10 includes an electrolyte membrane 12, an anode electrode 14 disposed on one surface of the electrolyte membrane 12, and a cathode electrode 16 disposed on the other surface of the electrolyte membrane 12. can be provided. Since this membrane-electrode assembly 10 has the same structure as the membrane-electrode assembly 10 used in a conventional unit cell, a detailed description of the membrane-electrode assembly 10 will be omitted.

Next, the first microporous layer 20 is disposed on one side of the anode electrode 14 so as to be located on the outer side of the unit cell 1 compared to the anode electrode 14, and the second microporous layer 30 is the cathode It is disposed on one surface of the cathode electrode 16 so as to be located on the outer side of the unit cell 1 compared to the electrode 16.

The first microporous layer 20 may be a gas diffusion layer or a carbon fiber layer in which a carbon support is impregnated with carbon fibers.

The carbon fiber layer may be configured to have smaller pores than gas diffusion layers used in conventional unit cells.

The second fine porous layer 30 may be composed of a carbon fiber layer having smaller pores than a gas diffusion layer used in a typical unit cell.

For example, the microporous layers 20 and 30 are made of carbon powder such as carbon black, acetylene black carbon, black pearls carbon, and polytetrafluoroethylene. It can be composed of a mixture of hydrophobic materials of the series.

2 to 5 are plan views of the first conductor plate.

Next, the first conductor plate 40 is disposed on one surface of the first micro-porous layer 20 so as to be located outside the unit cell 1 compared to the first micro-porous layer 20 .

The first microporous layer 20 has an electrical conductivity of about 400 S/m. The first conductor plate 40 is prepared to have higher electrical conductivity than the first microporous layer 20 . For example, the first conductor plate 40 may be formed of a metal material having an electrical conductivity of about 20000 S/m.

As shown in FIG. 1 , the first conductor plate 40 is a conductive portion interposed between one of the land portions 52 of the first separator 50 and one surface of the first microporous layer 20, respectively. It may have channel parts 42 interposed between each of the channels 41 and any one of the channel parts 54 of the first separator 50 and one surface of the first microporous layer 20 .

As shown in FIG. 1 , each of the conductive parts 41 has land parts 52 such that one surface contacts one of the land parts 52 and the other surface contacts one surface of the first microporous layer 20 . ) Is interposed between one side of any one of the first microporous layer (20). As shown in FIG. 2 , each of the conductive parts 41 preferably has a flat plate shape having a predetermined thickness, but is not limited thereto. Each of the conductive parts 41 may electrically connect one of the land parts 52 and the first microporous layer 20 to each other.

The shape of the passage parts 42 is not particularly limited.

For example, as shown in FIG. 2 , at least one of the passage parts 42 is a connection wire 43 formed to electrically connect at least one of the conductive parts 41 and the first microporous layer 20. ), and a passage hole 44 formed to communicate any one of the channel portions 54 and the pores of the first microporous layer 20 .

As shown in FIG. 2 , the connecting wire 43 may have a thin thread shape elongated along the longitudinal direction. As shown in FIG. 1, the bottom surface of the connection wire 43 is seated on one surface of the first microporous layer 20, and both ends of the connection wire 43 are respectively attached to one of the conductive parts 41. Connected. However, it is not limited, and only one end of the connection wire 43 may be connected to any one of the conductive parts 41 . Through this, the connection wire 43 may electrically connect at least one of the conductive parts 41 and the first microporous layer 20 .

The number of these connection wires 43 formed is not particularly limited. For example, as shown in FIG. 2 , a plurality of connection wires 43 may be formed at predetermined intervals in at least one of the flow path parts 42 .

As shown in FIG. 2 , the passage hole 44 is a pair of conductive parts positioned adjacent to each other so that any one of the channel parts 54 and the pores of the first microporous layer 20 can communicate with each other. 41) is perforated between the middle. The number of these passage holes 44 is not particularly limited. For example, as shown in FIG. 2 , a plurality of passage holes 44 may be formed at predetermined intervals in at least one of the passage parts 42 . These passage holes 44 preferably have a predetermined size so that hydrogen flowing through the channel portions 54 can smoothly move through the passage holes 44 . For example, considering the high diffusivity of hydrogen, the passage holes 44 may have a predetermined diameter so that the first conductor plate 40 has a porosity of about 0.7.

For example, as shown in FIGS. 3 to 5, at least one of the passage parts 42 is formed to electrically connect at least one of the conductive parts 41 and the first microporous layer 20. It has a rib 45, a first flow hole 46, a second flow hole 47, etc., each formed to communicate any one of the channel portions 54 and the pores of the first microporous layer 20. can

As shown in FIG. 3 , the connecting rib 45 may have a rod shape elongated along the longitudinal direction. The bottom surface of the connection rib 45 is seated on one surface of the first microporous layer 20, and both ends of the connection rib 45 are connected to one of the conductive parts 41, respectively. However, it is not limited thereto, and only one end of the connection rib 45 may be connected to any one of the conductive parts 41 . Through this, the connection rib 45 may electrically connect at least one of the conductive parts 41 and the first microporous layer 20 .

The number of formed connection ribs 45 is not particularly limited. For example, as shown in FIG. 3 , a plurality of connecting ribs 45 may be formed at predetermined intervals in at least one of the flow path parts 42 .

As shown in FIG. 3 , the first passage hole 46 is a pair of conductive parts positioned adjacent to each other so that any one of the channel parts 54 and the pores of the first microporous layer 20 can communicate with each other. It is perforated between the sills (41). The number of the first passage holes 46 is not particularly limited. For example, as shown in FIG. 3 , a plurality of first passage holes 46 may be formed at predetermined intervals in at least one of the passage parts 42 .

As shown in FIG. 4 , the second passage hole 47 is formed by at least one of the connection ribs 45 so that any one of the channel parts 54 and the pores of the first microporous layer 20 communicate with each other. drilled into one The number of the second passage holes 47 is not particularly limited. For example, as shown in FIG. 4 , at least one of the connecting ribs 45 may have a plurality of second passage holes 47 drilled at predetermined intervals. The shape of the second passage holes 47 is not particularly limited. For example, as shown in FIGS. 4 and 5 , the second flow holes 47 may have various shapes such as circular and polygonal shapes.

Next, as shown in FIG. 1 , the first separator 50 may include land parts 52 and channel parts 54 that are alternately formed along a predetermined direction. The land portions 52 have a valley shape, and the channel portions 54 have a mountain shape. The first separation plate 50 is disposed on one surface of the first conductor plate 40 so that the land parts 52 are seated on one of the conductive parts 41 . Then, each of the land parts 52 may be electrically connected to one of the conductive parts 41, and the channel parts 54 may constitute a hydrogen flow path for transporting hydrogen and generated water, respectively.

6 is a view showing how electrons and reactive gases are transferred through the first conductor plate.

Hereinafter, an aspect in which electrons and hydrogen are transferred through the first conductor plate 40 will be described by taking a case where the passage part 42 has the connection wire 43 and the passage hole 44 as an example.

First, hydrogen supplied from an external hydrogen supply source is transported through the channel units 54 .

Next, hydrogen passing through the channel portions 54 is introduced into the first microporous layer 20 through the flow hole 44 and then diffused in the first microporous layer 20 to the anode electrode ( 14) enters.

Subsequently, the hydrogen introduced into the anode electrode 14 is oxidized and separated into hydrogen ions and electrons.

Next, hydrogen ions are transferred to the cathode electrode 16 through the electrolyte membrane 12, and electrons are transferred to the first microporous layer 20 and then to the connecting wires 43 and the conductive parts 41. do.

Subsequently, the electrons transferred to the connecting wires 43 are transferred to the conductive parts 41 electrically connected to the connecting wires 43 .

Next, electrons transferred to the conductive parts 41 through the first microporous layer 20 and the connection wires 43 are transferred to the land parts 52 .

On the other hand, residual hydrogen that is not separated into hydrogen ions and electrons among the hydrogen introduced into the cathode electrode 16 is re-introduced into the channel portions 54 through the first microporous layer 20 and the flow hole 44, and then , may be discharged through the channel portions 54.

When the unit cell is prepared so that the first microporous layer 20 and the land portions 52 are in direct contact with the first conductor plate 40 omitted, channel portions among the electrons transferred to the first microporous layer 20 Electrons transferred to one region of the first microporous layer 20 facing 54 move the inside of the first microporous layer 20 in the direction of the surface of the first microporous layer 20 to form land portions. After being transferred to the other area of the first microporous layer 20 facing 52, it is transferred to the land parts 52. However, the microporous layers 20 and 30 have a thickness of about 10 μm, and the channel portion 54 of the first separator 50 has a width of 100 μm to 1000 μm. For this reason, the distance between one area of the first microporous layer 20 and the other area of the first microporous layer 20 is significantly longer than the thickness of the first microporous layer 20 . Therefore, when the unit cell is provided so that the first microporous layer 20 and the land portions 52 are in direct contact, the electrical resistance of the unit cell is increased due to the movement of electrons in the plane direction of the first microporous layer 20. As it increases, it becomes a cause of performance degradation of the unit cell.

However, electrons have a property of being transferred from a material with low electrical conductivity to a material with high electrical conductivity. That is, when a material with low electrical conductivity and a material with high electrical conductivity come into contact, electrons have a characteristic of moving through the material with high electrical conductivity. For this reason, when the first conductor plate 40 is interposed between the first microporous layer 20 and the first separator 50, the channel portions 54 among the electrons transferred to the first microporous layer 20 Electrons transferred to one area of the first microporous layer 20 facing each other are transferred to the connecting wires 43 instead of being transferred to another area of the first microporous layer 20 . Through this, the first conductor plate 40 can reduce the movement distance of electrons transferred to the first microporous layer 20 in the plane direction of the first microporous layer 20 . Therefore, the first conductor plate 40 can improve the performance of the unit cell 1 by reducing the electrical resistance of the unit cell 1 .

7 to 9 are plan views of the second conductor plate.

Next, the second conductor plate 60 is disposed on one surface of the second micro-porous layer 30 so as to be located outside the unit cell 1 compared to the second micro-porous layer 30 .

The second fine porous layer 30 has an electrical conductivity of about 400 S/m. The second conductor plate 60 is prepared to have higher electrical conductivity than the second microporous layer 30 . For example, the second conductor plate 60 may be formed of a metal material having an electrical conductivity of about 20000 S/m.

As shown in FIG. 7 , the second conductor plate 60 may have a flat plate shape having a predetermined thickness. As shown in FIG. 1, the second conductor plate 60 is formed by connecting the porous metal body 70 and the second microporous layer 30 so as to be in contact with the porous metal body 70 and the second microporous layer 30, respectively. intervened between The second conductor plate 60 may electrically connect the porous metal body 70 and the second microporous layer 30 .

As shown in FIG. 7 , the second conductor plate 60 has passage holes 61 and 62 formed to communicate the pores of the second microporous layer 30 and the pores of the metal porous body 70. can be provided In general, the porous metal body 70 has a porosity of about 0.9. The passage holes 61 and 62 are preferably formed such that the porosity of the second conductor plate 60 is lower than that of the porous metal body 70 . For example, the passage holes 44 may be formed so that the second conductor plate 60 has a porosity of about 0.7.

Meanwhile, the porous metal body 70 may be formed of a metal foam formed by foaming a metal material so that metal wires are coupled in a mesh shape. For this reason, if some of the metal wires protrude long toward the second microporous body due to the random geometric shapes of the metal wires, the membrane-electrode assembly 10 is attached to the metal wires penetrating the second microporous layer 30. can be damaged by Then, an overvoltage occurs due to a short between the anode electrode 14 and the cathode electrode 16, resulting in damage to the unit cell 1 or a hole in the membrane-electrode assembly 10 formed by the metal wires. A fire may occur due to a direct reaction between hydrogen introduced into the anode electrode 14 and oxygen introduced into the cathode electrode 16.

However, in order to stably maintain the performance of the unit cell 1, it is required that the contact state of the components within the unit cell 1 be continuously maintained. To this end, surface pressure applied from a fastening member such as a bolt is applied to the components in the unit cell 1 . In particular, as shown in FIG. 1, since the first separator 50 is arranged so that only the land portions 52 selectively press the first conductor plate 40, the entire area of the components in the unit cell 1 Among them, surface pressure is intensively applied to an area located on the same line as the land portions 52 based on the thickness direction of the membrane-electrode assembly 10 . As a result, the metal wires positioned in the area located on the same line as the land portions 52 based on the thickness direction of the membrane-electrode assembly 10 among the entire area of the porous metal body 70 are connected to the second microporous layer 30. ) and the membrane-electrode assembly 10 can be stabbed relatively strongly. Therefore, damage to the second microporous layer 3 and the membrane-electrode assembly 10 due to the metal wires is a land based on the thickness direction of the membrane-electrode assembly 10 in the entire area of the porous metal body 70. It occurs intensively in a region located on the same line as the parts 52 .

To solve this problem, the second conductor plate 60 is preferably provided to protect the second microporous layer 30 and the membrane-electrode assembly 10 from metal wires.

For example, as shown in FIG. 7 , the passage holes 61 and 62 are located on the same line as one of the land portions 52 based on the thickness direction of the membrane-electrode assembly 10 . Same as any one of the first flow holes 61 formed in the first region 63 of the two-conductor plate 60 and the channel portions 54 based on the thickness direction of the membrane-electrode assembly 10 Second passage holes 62 may be formed in the second region 64 of the second conductor plate 60 positioned on the line, respectively. The shapes of the first flow holes 61 and the second flow holes 62 are not particularly limited. For example, as shown in FIGS. 7 and 8 , the first flow holes 61 and the second flow holes 62 may have various shapes such as circular and polygonal shapes.

The first passage holes 61 and the second passage holes 62 may be formed such that the porosity of the first region 63 is lower than that of the second region 64 . To this end, the first flow holes 61 may have a smaller diameter than the second flow holes 62 . In particular, the first flow holes 61 may have a smaller diameter than the metal wires. Then, the metal wires are blocked by the second conductor plate 60 and do not reach the second microporous layer 30 and the membrane-electrode assembly 10 . Through this, the second conductor plate 60 can effectively prevent the second microporous layer 30 and the membrane-electrode assembly 10 from being damaged by the metal wires. In addition, in the second region 64, where the possibility of damage to the second microporous layer 30 and the membrane-electrode assembly 10 is lower than that of the first region 63, air and air through the second passage hole 62 The generated water moves actively.

On the other hand, the second conductor plate 60 has been described as having flow holes 61 and 62 formed to communicate the pores of the porous metal body 70 with the pores of the second microporous layer 30, but this It is not limited.

For example, as shown in FIG. 9, the second conductor plate 60 electrically connects the second microporous layer 30 and the porous metal body 70, and at the same time, the second microporous layer 30 It may have a mesh structure so that the pores of the porous metal body 70 can communicate with the pores of the metal body 70 . More specifically, the second conductor plate 60 includes first meshes 65 respectively formed in the first region 63 and second meshes 66 respectively formed in the second region 64. can be provided

In particular, the first meshes 65 and the second meshes 66 may be formed such that the porosity of the first region 63 is lower than that of the second region 64 . Through this, the second conductor plate 60 can prevent the membrane-electrode assembly 10 from being damaged by the metal wires.

Next, as shown in FIG. 1 , the porous metal body 70 is disposed on one side of the second conductor plate 60 so as to be located on the outer side of the unit cell 1 compared to the second conductor plate 60 . The metal porous body 70 is preferably formed by foaming a metal material to have a predetermined porosity, but is not limited thereto. The metal porous body 70 electrically connects the second conductor plate 60 and the second separator plate 80 and provides an air flow path for transporting air and product water through pores formed therein. can

Next, as shown in FIG. 1 , the second separator 80 is disposed on one surface of the porous metal body 70 so as to be electrically connected to the porous metal body 70 . The second separator 80 may prevent air and generated water flowing through the pores of the porous metal body 70 from leaking to the outside. In addition, the second separator 80 may transfer electrons separated from hydrogen at the anode electrode 14 to the porous metal body 70 .

10 is a diagram illustrating how electrons and reactive gases are transferred through a second conductor plate.

Hereinafter, the transfer of electrons and air through the second conductor plate 60 will be described by taking the case where the second conductor plate 60 has the passage holes 61 and 62 as an example.

First, air supplied from an air supply source is transferred through pores of the porous metal body 70 , and electrons transferred to the second separator 80 are transferred to the porous metal body 70 .

Next, the air passing through the pores of the porous metal body 70 flows into the second microporous layer 30 through the passage holes 61 and 62, and then diffuses in the second microporous layer 30. into the cathode electrode 16. At the same time, the electrons transferred to the porous metal body 70 are transferred to the cathode electrode 16 through the second conductor plate 60 and the second microporous layer 30 sequentially.

Subsequently, oxygen in the air flowing into the cathode electrode 16, hydrogen ions flowing into the cathode electrode 16, and electrons transferred to the cathode electrode 16 are combined at the cathode electrode 16, and by this reduction reaction In the cathode electrode 16, electrical energy and product water are generated.

As described above, the porosity of the second conductor plate 60 is lower than that of the porous metal body 70 . Therefore, the contact area between the second conductor plate 60 and the second microporous layer 30 is the same as that of the porous metal body 70 when the porous metal body 70 and the second microporous layer 30 are brought into direct contact. 2 It is wider than the contact area of the microporous layer 30. The electrons transferred to the second microporous layer 30 are diffused while moving inside the second microporous layer 30 in the plane direction of the second microporous layer 30, and then transferred to the cathode electrode 16. do. That is, the electrons transferred to the second microporous layer 30 are diffused in the plane direction of the second microporous layer 30 so as to be uniformly distributed inside the second microporous layer 30, and then the cathode electrode ( 16) is passed on. By the way, when the second conductor plate 60 is interposed between the second microporous layer 30 and the porous metal body 70, the electrons have a higher electrical conductivity than the second microporous layer 30. The second conductor plate ( 60) is delivered to the second microporous layer 30 in a uniformly diffused state. Therefore, when the second conductor plate 60 is interposed between the second microporous layer 30 and the porous metal body 70, electrons are directly transferred from the porous metal body 70 to the second microporous layer 30. Compared to, it is possible to reduce the distance that electrons move in the surface direction of the second microporous layer 30 for uniform distribution of electrons. Through this, the second conductor plate 60 can improve the performance of the unit cell 1 by reducing the electrical resistance of the unit cell 1 .

The above description is merely an example of the technical idea of the present invention, and various modifications and variations can be made to those skilled in the art without departing from the essential characteristics of the present invention.

Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed according to the claims below, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

1: unit cell for fuel cell
10: membrane-electrode assembly
12: electrolyte membrane
14: anode electrode
16: cathode electrode
20: first microporous layer
30: second microporous layer
40: first conductor plate
41: conduction part
42: Euro part
43: connecting wire
44: Eurohole
45: connecting rib
46: first euro hole
47: second euro hole
50: first separator plate
52: land part
54: channel unit
60: second conductor plate
61: first euro hole
62: second euro hole
63: first area
64: second area
65: first mesh
66: second mesh
70: metal porous body
80: second separator plate
_H2 : Hydrogen
Air: air
e ^- : e

Claims (18)

membrane-electrode assembly;
a microporous layer disposed on one side of the membrane-electrode assembly;
a conductor plate having electrical conductivity higher than that of the microporous layer and disposed on one surface of the microporous layer to be electrically connected to the microporous layer; and
Land parts and channel parts are formed alternately along a predetermined direction, and the land parts are electrically connected to the conductor plate and the channel parts form a reactive gas passage for transporting a reactive gas at the same time as the land parts are electrically connected to the conductor plate. Including a separator disposed on one side of the plate,
The conductor plate is interposed between conductive parts respectively interposed between any one of the land parts and the one surface of the microporous layer, and between any one of the channel parts and the one surface of the microporous layer, respectively, and the reaction Equipped with passage parts provided to allow gas to pass through;
At least one of the passage parts may include a connection wire formed to electrically connect at least one of the conductive parts and the microporous layer, and a passage formed to communicate any one of the channel parts with pores of the microporous layer. A unit cell for a fuel cell characterized in that it has a hole. delete delete membrane-electrode assembly;
a microporous layer disposed on one side of the membrane-electrode assembly;
a conductor plate having electrical conductivity higher than that of the microporous layer and disposed on one surface of the microporous layer to be electrically connected to the microporous layer; and
Land parts and channel parts are formed alternately along a predetermined direction, and the land parts are electrically connected to the conductor plate and the channel parts form a reactive gas passage for transporting a reactive gas at the same time as the land parts are electrically connected to the conductor plate. Including a separator disposed on one side of the plate,
The conductor plate is interposed between conductive parts respectively interposed between any one of the land parts and the one surface of the microporous layer, and between any one of the channel parts and the one surface of the microporous layer, respectively, and the reaction Equipped with passage parts provided to allow gas to pass through;
At least one of the flow passage parts, a connecting rib formed to electrically connect at least one of the conductive parts and the microporous layer, and a second formed to communicate any one of the channel parts and the pores of the microporous layer. 1 A unit cell for a fuel cell characterized in that it has a flow hole. According to claim 4,
At least one of the channel parts has a second flow hole formed in the connection rib so that any one of the channel parts and the pores of the microporous layer communicate with each other. According to claim 1,
The microporous layer is composed of a gas diffusion layer or a carbon fiber layer in which a carbon support is impregnated with carbon fibers, and the conductor plate is a unit cell for a fuel cell, characterized in that composed of a metal material having higher electrical conductivity than the microporous layer. . membrane-electrode assembly;
a microporous layer disposed on one side of the membrane-electrode assembly;
a conductor plate having electrical conductivity higher than that of the microporous layer and disposed on one surface of the microporous layer to be electrically connected to the microporous layer;
a porous metal body electrically connected to the conductor plate and disposed on one surface of the conductor plate to form a reaction gas passage for transporting a reaction gas; and
A unit cell for a fuel cell comprising a first separator disposed on one surface of the porous metal body to be electrically connected to the porous metal body. According to claim 7,
The conductor plate is a unit cell for a fuel cell, characterized in that it is provided with flow holes connecting the pores of the metal porous body and the pores of the microporous layer. According to claim 8,
The flow holes are formed such that the porosity of the conductor plate is lower than the porosity of the metal porous body. According to claim 8,
The metal porous body is composed of a metal foam formed by foaming a metal material so that metal wires are coupled to form a mesh,
The flow holes are unit cells for a fuel cell, characterized in that they have a smaller diameter than the metal wires. According to claim 7,
Land parts and channel parts are alternately formed along a predetermined direction, and the land parts are formed on the other surface of the MEA to provide surface pressure to the MEA in the thickness direction of the MEA. A unit cell for a fuel cell further comprising a second separator disposed thereon. According to claim 11,
The conductor plate includes first flow holes each formed in a first region of the conductor plate positioned on the same line as any one of the land parts with respect to the thickness direction, and the channel parts with respect to the thickness direction. A unit cell for a fuel cell, characterized in that it includes second passage holes each formed in a second region of the conductor plate positioned on the same line as one of the second passage holes. According to claim 12,
The first flow path holes and the second flow path holes are formed such that the porosity of the first region is lower than that of the second region. According to claim 12,
The unit cell for a fuel cell, characterized in that the first flow hole has a smaller diameter than the second flow hole. According to claim 12,
The metal porous body is composed of a metal foam formed by foaming a metal material so that metal wires are coupled to form a mesh,
The unit cell for a fuel cell, characterized in that the first passage holes have a diameter smaller than that of the metal wires. According to claim 11,
The conductor plate may include first meshes respectively formed in a first region of the conductor plate positioned on the same line as one of the land parts based on the thickness direction, and among the channel parts based on the thickness direction. A unit cell for a fuel cell comprising second meshes each formed in a second region of the conductor plate positioned on the same line as one of the second meshes. According to claim 16,
Each of the first meshes is formed such that the porosity of the first region is lower than that of the second region. According to claim 7,
The microporous layer is composed of a carbon fiber layer,
The conductor plate is a unit cell for a fuel cell, characterized in that composed of a metal material having a higher electrical conductivity than the microporous layer.

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