KR102621729B1 - Cylindrical fuel cell - Google Patents

Abstract

The present invention relates to a cylindrical fuel cell, which minimizes the area where water generated in the separator plate accumulates, allows the generated water to be discharged quickly, and uses a material of high electrical conductivity for the separator plate to form a fuel cell. Efficiency can be increased.

Description

Cylindrical fuel cell

The present invention relates to polymer electrolyte membrane fuel cells, and particularly to fuel cells with a cylindrical structure.

Hydrogen vehicle fuel cells use a stack form in which unit cells are stacked and assembled to meet the required output level.

The unit cell consists of a separator and a membrane-electrode assembly (MEA).

Referring to FIG. 1, the existing fuel cell structure will be described.

The existing fuel cell is a type in which separator plates 10 are stacked and fastened together at an appropriate pressure, and the vertical surface 11 of the flow path serves to support the pressure generated when multiple separator plates 10 are stacked.

In order to increase the reactivity of the supplied hydrogen and oxygen in the air, the hydrogen and air must be in contact with the membrane electrode assembly 20 as much as possible along the flow path. To this end, the supplied hydrogen and oxygen must be distributed equally along each flow path. It must be designed.

However, if water, which is a reaction product of hydrogen and oxygen in the air, accumulates on the horizontal surface 12, which is the part where the separator plate 10 and the membrane electrode assembly 20 come into contact, and the air passage 40 through which air flows, resistance is generated. There is a problem in that air does not flow behind the air passage 40 or the reaction area of the membrane electrode assembly 20 is reduced.

For example, Korean Patent Document No. 10-1008738 relates to a fuel cell assembly, including a plurality of cell parts 120, each of which has a cylindrical shape, but can easily remove accumulated water droplets. There is no awareness that allows it to escape, and there is a problem that results in a reduction in the response area.

In addition, as another example, Korean Patent Document No. 10-0747863 discloses a first electrode plate 10, a first gasket 20, a membrane 30, a second gasket 40, and a second electrode plate 50. ), but there is no recognition that allows the accumulated water droplets to easily escape, and there is a problem in that the water droplets cannot easily escape, resulting in a reduction in the reaction area.

In addition, for another example, Korean Patent Document No. 10-1875684 relates to a liquid fuel cell used by filling the inside of the first electrode body 120 with fuel material 110, and allows accumulated water droplets to easily escape. There is no recognition, and there is a problem that results in a reduction in the response area.

In addition, an appropriate number of vertical surfaces 11 in the structure of the separator 10 is essential to maintain its shape during the process of fastening the plurality of separators 10, and the separator 10 generates electricity from the supplied hydrogen. It must have high electrical conductivity to transmit electrons, and must have rigidity to support the overall structure.

However, in the case of the three patents above, they were just the same as the existing separator plate, and the role of the support was not separated from the separator plate.

(Patent Document 1) Korean Patent Document No. 10-1008738

(Patent Document 2) Korean Patent Document No. 10-0747863

(Patent Document 3) Korean Patent Document No. 10-1875684

The present invention was created to solve the above problems.

Specifically, the present invention was developed to minimize the area where water generated during a chemical reaction between supplied hydrogen and oxygen in the air is accumulated and to quickly discharge the generated water.

In addition, the present invention is intended to distinguish between the cell support role and the electrical conduction role of the separator plate and use materials optimized for each role.

One embodiment of the present invention for solving the above problems includes a plurality of first cylindrical solid rods 110 made of an electrically conductive material spaced apart from each other, and a first cylindrical solid rod 110 of the electrically conductive material. A separation plate 100 including a plurality of second cylindrical solid rods 120 of electrically conductive material located radially outwardly and spaced apart from each other; a membrane electrode assembly (200) located radially outwardly of the first cylindrical solid rods 110 of the plurality of electrically conductive materials and radially inward of the plurality of second cylindrical solid rods 120 of the electrically conductive material; and a first flow path 310 in which the plurality of first cylindrical solid rods 110 of the electrically conductive material are located to supply hydrogen, and the plurality of second cylindrical solid rods 120 of the electrically conductive material are located to supply oxygen. a flow path 300 including a second flow path 320 supplying water; Provides a fuel cell including.

In one embodiment, the first cylindrical solid rod 110 of the plurality of electrically conductive materials and the second cylindrical solid rod 120 of the plurality of electrically conductive materials are located on the inner and outer sides of the membrane electrode assembly 200, respectively. In one embodiment, the membrane electrode assembly 200 has a hollow cylindrical shape and is formed to extend a predetermined length in the vertical direction, and the plurality of first cylindrical solid rods 110 of the electrically conductive material. and the plurality of second cylindrical solid rods 120 of electrically conductive material are each arranged in a circle along the membrane electrode assembly 200.

In one embodiment, the first cylindrical solid rod 110 of the plurality of electrically conductive materials and the second cylindrical solid rod 120 of the plurality of electrically conductive materials are each formed in a circular shape along the membrane electrode assembly 200. Arranged concentrically, one of the first cylindrical solid rods 110 of the plurality of electrically conductive materials and the second cylindrical solid rod 110 of the plurality of electrically conductive materials are arranged concentrically. Each of the second cylindrical solid rods 120 of an electrically conductive material of the rods 120 may be positioned concentrically but with radially different diameters.

In one embodiment, a central portion 410 located inside the first flow path 310, an extension portion 420 extending from the central portion 410 and contacting the membrane electrode assembly 200, and formed in plural numbers. ) may further include a cell support 400, including a cell supporter 400.

In one embodiment, an air inlet 500 communicates with the second flow path 320 and introduces air; It may further include.

In one embodiment, a shell 600 located outside the second flow path 320; It may further include.

In one embodiment, the first cylindrical solid rod 110 of the plurality of electrically conductive materials and the plurality of second cylindrical solid rods 120 of the electrically conductive material are each adjacent to one another of the second cylindrical solid rod 110 of the electrically conductive material. The cylindrical solid bar 120 and the first cylindrical solid bar 110 made of an electrically conductive material adjacent to each other may be arranged in a zigzag manner.

According to the present invention, the following effects are achieved.

The present invention achieves the effect of increasing the reactivity of the fuel cell by arranging the cylindrical solid rods in a zigzag manner, thereby minimizing the area where water accumulates in the area where the separator contacts and the air passage.

In addition, the present invention achieves the effect of increasing the efficiency of the fuel cell by dividing the supporting role and the electrical conduction role of the separator by using materials optimized for each role.

Figure 1 is a diagram to explain problems with conventional fuel cells.
Figure 2 is a perspective view of a fuel cell according to the present invention.
Figure 3 is a view of the fuel cell according to the present invention seen from above.
Figure 4 is a cross-sectional view of a fuel cell according to the present invention.

In some cases, in order to avoid ambiguity of the concept of the present invention, well-known structures and devices may be omitted or may be shown in block diagram form focusing on the core functions of each structure and device.

Additionally, in describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. The terms described below are terms defined in consideration of functions in the embodiments of the present invention, and may vary depending on the intention or custom of the user or operator. Therefore, the definition should be made based on the contents throughout this specification.

The fuel cell according to the present invention includes a cylindrical solid rod 100 of an electrically conductive material, a membrane electrode assembly 200, a flow path 300, a cell support 400, an air inlet 500, and a shell 600.

2 to 4, a fuel cell according to the present invention will be described.

The cylindrical solid rod 100 made of an electrically conductive material comes into contact with the membrane electrode assembly 200, which will be described later, and serves to transmit electrons.

The cylindrical solid rod 100 of an electrically conductive material includes a plurality of first cylindrical solid rods 110 of an electrically conductive material and a plurality of second cylindrical solid rods 120 of an electrically conductive material.

A plurality of first cylindrical solid rods 110 made of electrically conductive material are located and spaced apart from each other.

At this time, the distance at which the first cylindrical solid rods 110 of electrically conductive material are spaced apart from each other is preset.

The first cylindrical solid rod 110 of electrically conductive material is positioned radially outward of the central portion 410, which will be described later.

In the present invention, the cell support 400 is provided separately and includes a central portion 410 and an extension portion 420, and is formed to support the membrane electrode assembly 200 and the fuel cell. A detailed explanation of this will be provided later.

The second cylindrical solid rod 120 of an electrically conductive material is located radially outward of the first cylindrical solid rod 110 of an electrically conductive material, and is connected to the first cylindrical solid rod 110 of an electrically conductive material and a membrane electrode assembly described later. (200) is in between.

The first cylindrical solid rod 110 made of an electrically conductive material and the plurality of second cylindrical solid rods 120 made of an electrically conductive material are positioned respectively inside and outside the membrane electric power supply assembly 200, which will be described later, at an appropriate pressure. At this time, the second cylindrical solid rod 120 of the electrically conductive material may be arranged concentrically with the first cylindrical solid rod 110 of the electrically conductive material and may be arranged in a circle, and a detailed description thereof will be described later.

A plurality of second cylindrical solid rods 120 made of electrically conductive material are located and spaced apart from each other.

At this time, the distance between the second cylindrical solid bars 120 of the electrically conductive material is preset, but is limited to the same distance as the distance between the first cylindrical solid bars 110 of the electrically conductive material. no.

The number and size of the first cylindrical solid rod 110 of an electrically conductive material and the second cylindrical solid rod 120 of an electrically conductive material are not limited to those shown.

At this time, the first cylindrical solid rod 110 of a plurality of electrically conductive materials and the second cylindrical solid rod 120 of a plurality of electrically conductive materials are all arranged in a circle, and the second cylindrical solid rod of an electrically conductive material ( 120) is located radially outward of the first cylindrical solid rod 110 of electrically conductive material, such that the number of second cylindrical solid rods 120 of electrically conductive material is equal to that of the first cylindrical solid rod 110 of electrically conductive material. It may be positioned to be more than the number, but is not limited thereto.

An end plate (not shown) may be positioned to support the first cylindrical solid rod 110 of electrically conductive material and the second cylindrical solid rod 120 of electrically conductive material, respectively.

The first cylindrical solid rod 110 of an electrically conductive material and the second cylindrical solid rod 120 of an electrically conductive material extend a predetermined length in the longitudinal direction.

Accordingly, the water generated in the membrane electrode assembly 200 is easily discharged in the direction of gravity through the first cylindrical solid rod 110 made of an electrically conductive material and the second cylindrical solid rod 120 made of an electrically conductive material.

The first cylindrical solid rod 110 of electrically conductive material and the second cylindrical solid rod 120 of electrically conductive material may extend longitudinally to correspond to the longitudinal length of the fuel cell.

The first cylindrical solid rod 110 of an electrically conductive material and the second cylindrical solid rod 120 of an electrically conductive material may be formed to have the same diameter, but are not limited thereto.

In addition, the first cylindrical solid rod 110 made of a plurality of electrically conductive materials and the second cylindrical solid rod 120 made of a plurality of electrically conductive materials are positioned to contact each other on the inside and outside of the membrane electrode assembly 200, as described above. As described above, each of the first cylindrical solid rods 110 made of a plurality of electrically conductive materials is positioned to be spaced apart from each other, and each of the second cylindrical solid rods 120 made of a plurality of electrically conductive materials are positioned to be spaced apart from each other.

The first cylindrical solid bar 110 of an electrically conductive material and the second cylindrical solid bar 120 of an electrically conductive material are each formed in a cylindrical shape, and the area of the contacting portion is minimized to minimize water accumulation in the contacting portion. You can.

In addition, the first flow path 310 and the second flow path 320 are formed to facilitate diffusion of the air and hydrogen supplied to the membrane electrode assembly 200, thereby increasing the reactivity of the supplied air and hydrogen. .

Additionally, in another embodiment of the present invention, the first cylindrical solid rod 110 of an electrically conductive material and the second cylindrical solid rod 120 of an electrically conductive material are arranged in a zigzag manner with each other.

The first cylindrical solid rod 110 made of a plurality of electrically conductive materials and the second cylindrical solid rod 120 made of a plurality of electrically conductive materials are each arranged in a circle along the membrane electrode assembly 200, but concentrically.

Electricity of any one of the first cylindrical solid rod 110 of a plurality of electrically conductive materials and the second cylindrical solid rod 120 of a plurality of electrically conductive materials Each of the second solid cylindrical rods 120 of conductive material is located at concentric, but radially different diameters.

The first cylindrical solid rod 110 made of a plurality of electrically conductive materials and the second cylindrical solid rod 120 made of a plurality of electrically conductive materials are each connected to one of the adjacent second cylindrical solid rods 120 of an electrically conductive material. It is arranged in a zigzag manner with one adjacent first cylindrical solid rod 110 of electrically conductive material.

Accordingly, by increasing the contact area between the first cylindrical solid rod 110 of an electrically conductive material and the second cylindrical solid rod 120 of an electrically conductive material, the reactivity in the membrane electrode assembly 200 can be further maximized. there is.

Additionally, the first cylindrical solid rod 110 made of an electrically conductive material and the second cylindrical solid rod 120 made of an electrically conductive material may be formed of a material with high electrical conductivity. This will be described later.

The membrane electrode assembly 200 receives air and hydrogen, separates electrons from hydrogen or combines hydrogen ions and oxygen to generate water and generates electricity in this process.

The membrane electrode assembly 200 is located between the first cylindrical solid rod 110 made of a plurality of electrically conductive materials and the second cylindrical solid rod 120 made of a plurality of electrically conductive materials, and the membrane electrode assembly 200 conducts electricity. It is placed in contact with the first cylindrical solid rod 110 of conductive material and the second cylindrical solid rod 120 of electrically conductive material.

The membrane electrode assembly 200 is formed in the shape of a hollow cylinder, and a first cylindrical solid rod 110 of an electrically conductive material is located inside the membrane electrode assembly 200, and an electrically conductive material is positioned outside the membrane electrode assembly 200. A second cylindrical solid rod 120 of conductive material is positioned.

In the membrane electrode assembly 200, hydrogen supplied to the first flow path 310, which will be described later, can move to one surface of the membrane electrode assembly 200 along the first cylindrical solid rod 110 made of a plurality of electrically conductive materials.

As described above, the first cylindrical solid rod 110 of the electrically conductive material and the second cylindrical solid rod 120 of the electrically conductive material are each formed in a cylindrical shape and extend in the longitudinal direction, so that the first cylindrical solid rod 110 of the electrically conductive material The contact area between the rod 110 and the second cylindrical solid rod 120 made of an electrically conductive material is minimized, so that water generated as a result of the reaction can be easily discharged from the membrane electrode assembly 200.

In addition, the first cylindrical solid rod 110 of a plurality of electrically conductive materials and the second cylindrical solid rod 120 of a plurality of electrically conductive materials are the first cylindrical solid rod 110 of an electrically conductive material and the second cylindrical solid rod 110 of an electrically conductive material. The two cylindrical solid rods 120 are each formed in a cylindrical shape and spaced apart at a predetermined interval, so that the water generated in the membrane electrode assembly 200 flows into the first cylindrical solid rod 110 made of a plurality of electrically conductive materials. Water can be easily discharged because it does not accumulate between the first cylindrical solid rods 120 of the plurality of electrically conductive materials.

In the present invention, the membrane electrode assembly 200 is separately supported by the extension portion 420 of the cell support 400, which will be described later, and the membrane electrode assembly 200 includes a first cylindrical solid rod 110 of an electrically conductive material. and is not supported by a second cylindrical solid rod 120 of electrically conductive material.

Accordingly, the first cylindrical solid rod 110 of an electrically conductive material and the second cylindrical solid rod 120 of an electrically conductive material can be formed of a material suitable for electrical conduction, thereby increasing the reaction efficiency of the fuel cell according to the present invention. It can be increased.

The flow path 300 includes a first flow path 310 and a second flow path 320.

The first flow path 310 is a space formed between the membrane electrode assembly 200 and the center 410 in which a plurality of first cylindrical solid rods 110 made of an electrically conductive material are located.

The first flow path 310 communicates with a hydrogen inlet, which will be described later, and receives hydrogen flowing in from the hydrogen inlet.

The width of the first flow path 310 is sufficient to allow the hydrogen flowing in from the hydrogen inlet to flow. However, in order to increase the reactivity in the membrane electrode assembly 200, the first cylindrical solid rod 110 of an electrically conductive material is sufficient. It may be formed to be slightly larger than the diameter.

The second flow path 320 is a space formed between the membrane electrode assembly 200 and the shell 600 in which a plurality of second cylindrical solid rods 120 made of an electrically conductive material are located.

The second flow path 320 communicates with the air inlet 500 and receives air introduced from the air inlet 500.

The width of the second flow path 320 is sufficient to allow the air introduced from the air inlet 500 to flow, but in order to increase the reactivity in the membrane electrode assembly 200, a second cylindrical solid rod of an electrically conductive material ( It can be formed to be slightly larger than the diameter of 120).

The cell support 400 is positioned to support the membrane electrode assembly 200.

The cell support 400 includes a central portion 410 and an extension portion 420.

The center 410 is located inside the first flow passage 310. The central portion 410 is formed in a cylindrical shape and extends longitudinally.

The longitudinally extending length of the center 410 may be the same as the longitudinally extending length of the above-described first cylindrical solid rod 110 of the electrically conductive material and the second cylindrical solid rod 120 of the electrically conductive material. .

The extension portion 420 extends from the center 410 and comes into contact with the membrane electrode assembly 200. The extension portion 420 extends from the center 410 and is positioned to contact the membrane electrode assembly 200. The extension portion 420 is formed in plural pieces, and the extension portion 420 is in contact with the membrane electrode assembly 200. The first cylindrical solid rod 110 of electrically conductive material is not positioned.

The air inlet 500 is located on one side of the outer shell 600 and communicates with the second flow path 320 to introduce air.

The air inlet 500 may be formed on the side of the outer shell 600 to supply air to the side of the second flow path 320, but the location of the air inlet 500 is not limited thereto.

The present invention further includes a hydrogen inlet (not shown). The hydrogen inlet communicates with the first flow path 310 and hydrogen flows in.

The hydrogen inlet may be located below the first flow path 310, but the location of the hydrogen inlet is not limited thereto.

The outer shell 600 is a part that supports the fuel cell from the outside, is located outside the second flow path 320, and is located at the outermost side of the fuel cell.

Inside the shell 600, the above-described separator 100, membrane electrode assembly 200, flow path 300, and cell support 400 are located.

The outer shell 600 is formed to communicate with the second flow path 320 so that the air introduced from the air inlet 500 described above can move to the second flow path 320.

Above, the present invention has been described with reference to the embodiments shown in the drawings so that those skilled in the art can easily understand and reproduce the present invention, but these are merely illustrative examples, and various modifications and equivalent alternatives can be made by those skilled in the art from the embodiments of the present invention. It will be appreciated that embodiments are possible. Therefore, the scope of protection of the present invention should be determined by the scope of the patent claims.

10: Separator plate
11: vertical plane
12: horizontal plane
20: Membrane electrode assembly
30: Hydrogen Euro
40: air flow path
100: Cylindrical solid rod of electrically conductive material
110: First cylindrical solid rod of electrically conductive material
120: Second cylindrical solid rod of electrically conductive material
200: Membrane electrode assembly
300: Euro
310: 1st Euro
320: Second Euro
400: Cell support
410: center
420: extension part
500: air inlet
600: outer shell

Claims (8)

A fuel cell formed to stand in a vertical direction,
A plurality of first cylindrical solid rods 110 made of an electrically conductive material that are spaced apart from each other, and a plurality of electric rods located radially outward from the first cylindrical solid rods 110 of the plurality of electrically conductive materials and spaced apart from each other. A cylindrical solid rod (100) of electrically conductive material comprising a second cylindrical solid rod (120) of conductive material;
a membrane electrode assembly (200) located radially outwardly of the first cylindrical solid rods 110 of the plurality of electrically conductive materials and radially inward of the plurality of second cylindrical solid rods 120 of the electrically conductive material;
A first passage 310 in which the plurality of first cylindrical solid rods 110 of the electrically conductive material are located and a second passage 320 in which the plurality of second cylindrical solid rods 120 of the electrically conductive material are located. Euros (300) included; and
A cell comprising a central portion 410 located inside the first flow path 310, a plurality of extension portions 420 extending from the central portion 410 and contacting the membrane electrode assembly 200, and forming a plurality of extension portions 420. Includes a support 400;
The first cylindrical solid rods 110 of the plurality of electrically conductive materials and the second cylindrical solid rods 120 of the plurality of electrically conductive materials each have a cylindrical shape,
The plurality of first cylindrical solid rods 110 of electrically conductive material and the plurality of second cylindrical solid rods 120 of electrically conductive material are each formed to extend in the longitudinal direction,
The water generated in the membrane electrode assembly 200 is discharged in the direction of gravity along the first cylindrical solid rod 110 of the plurality of electrically conductive materials and the second cylindrical solid rod 120 of the plurality of electrically conductive materials. ,
fuel cell.
According to paragraph 1,
The first cylindrical solid rod 110 of the plurality of electrically conductive materials and the second cylindrical solid rod 120 of the plurality of electrically conductive materials are positioned to contact the inner and outer sides of the membrane electrode assembly 200, respectively.
fuel cell.
According to paragraph 2,
The membrane electrode assembly 200 has a hollow cylindrical shape and is formed to extend a certain length in the vertical direction,
The first cylindrical solid rod 110 of the plurality of electrically conductive materials and the second cylindrical solid rod 120 of the plurality of electrically conductive materials are each arranged in a circle along the membrane electrode assembly 200,
fuel cell.
According to paragraph 3,
The first cylindrical solid rod 110 of the plurality of electrically conductive materials and the second cylindrical solid rod 120 of the plurality of electrically conductive materials are each arranged in a circle along the membrane electrode assembly 200, but are concentrically arranged. ,
Any one of the plurality of first cylindrical solid rods 110 of the electrically conductive material and the second cylindrical solid rod 120 of the plurality of electrically conductive materials. Each of the second cylindrical solid rods 120 of electrically conductive material is concentric but located on radially different diameters,
fuel cell.
delete According to paragraph 1,
an air inlet 500 that communicates with the second flow path 320 and introduces air; Including,
fuel cell.
According to paragraph 1,
an outer shell 600 located outside the second flow path 320; Containing more,
fuel cell.
According to paragraph 4,
The first cylindrical solid rod 110 of the plurality of electrically conductive materials and the plurality of second cylindrical solid rods 120 of the electrically conductive material are each adjacent to each other. and are arranged in a zigzag manner with a first cylindrical solid rod 110 of an electrically conductive material adjacent to each other,
fuel cell.

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