KR20220062980A - Flat tubular solid-oxide fuel cell and stack structure using the same - Google Patents

Abstract

The present invention relates to a flat tubular solid oxide fuel cell and a stack structure using the same. The flat tubular solid oxide fuel cell comprises: a fuel cell having a plurality of transfer holes through which reactive gas is supplied; an assembly guide disposed at both ends of the fuel cell and having a concave groove formed on an upper surface corresponding to the fuel cell; and a first sealing sheet provided with a flexible sheet made of a sealing material and sealing a space between the fuel cell seated in the concave groove and the assembly guide and an upper surface of the assembly guide. The flat tubular solid oxide fuel cell and the stack structure using the same increase the safety of a flat tubular solid oxide fuel cell stack sealing structure operating at high temperatures, are composed of small and standardized parts to reduce manufacturing costs, and reduce the amount of expensive sealing materials used to reduce manufacturing unit costs.

Description

Flat tube solid oxide fuel cell and stack structure using same

The present invention relates to a flat tubular solid oxide fuel cell and a stack structure using the same, and specifically, it is possible to strengthen the sealing force by combining a cell stack and a manifold, thereby improving durability and increasing the lifespan of the cell stack. It relates to a flat tube type solid oxide fuel cell and a stack structure using the same.

A fuel cell refers to a cell that directly converts chemical energy generated according to an oxidation reaction into electrical energy. This fuel cell technology does not use fossil fuels and generates electric energy from materials abundantly present on the earth, such as hydrogen or oxygen, and thus corresponds to an eco-friendly future energy technology.

The fuel cell stack is composed of a plurality of fuel cell cells, and hydrogen is supplied to the fuel electrode and oxygen is supplied to the cathode, so that an electrochemical reaction proceeds in the form of a reverse reaction of water electrolysis, and electricity, heat, and water are generated by this reaction. Electric energy can be produced with high efficiency without causing pollution.

The fuel cell stack capable of direct energy conversion as described above is free from the limitation of the Carnot cycle, which acts as a limit in the conventional heat engine, and thus can increase the efficiency by more than 40%. There is no concern, and unlike the conventional heat engine, a mechanically moving part is unnecessary, so it is possible to reduce the size and has various advantages such as no noise. Accordingly, various technologies and research related to fuel cells are being actively conducted.

On the other hand, fuel cell stacks are classified in various ways according to the type of electrolyte. Oxide Fuel Cell), Polymer Electrolyte Membrane Fuel Cell (PEMFC), Methanol Fuel Cell (DMFC, Direct Methanol Fuel Cell), Alkaline Fuel Cell (AFC), etc.

These fuel cells have very diverse output ranges and uses, and a fuel cell demander selects and uses an appropriate fuel cell according to the purpose. In particular, solid oxide fuel cells (SOFCs) are relatively easy to control the position of the electrolyte, and there is no risk of electrolyte depletion because the position of the electrolyte is fixed. It has the advantage that it can be used in a wide range of applications.

In the solid oxide fuel cell according to the present invention, when hydrogen is supplied to an anode and oxygen is supplied to an anode, an electrochemical reaction occurs to produce electricity, and the reaction shown in Chemical Formula 1 below occurs.

[Formula 1]

Anode: 2H ₂ + 2O ^2- → 2H ₂ O + 4e-

Cathode: O ₂ + 4e- → 2O ^2-

Although such a solid oxide fuel cell is also used in the form of a single cell, it is usually composed of a stack type in which a plurality of them are stacked to increase output. In the case of a stack type in which a plurality of flat tube fuel cells are stacked as described above, it is preferable that the stacked unit cells be sealed by a sealing material to prevent gas leakage between the stacked unit cells.

However, in the case of a flat tube type solid oxide fuel cell, since it operates at a high temperature of about 500 to 1,000° C., the safety of the sealing structure is lowered, and the amount of expensive sealing material used increases due to the large number of sealing parts, thereby increasing the manufacturing cost.

Laid-open Patent Publication No. 10-2011-0044657 (2011.04.29.)

The present invention has been devised to solve the above-mentioned problems in the prior art, and an object of the present invention is to increase the safety of the sealing structure of a flat tube solid oxide fuel cell stack operating at a high temperature, and to increase the manufacturing cost because it is composed of small standardized parts. It is to provide a flat tube type solid oxide fuel cell and a stack structure using the same that can reduce the cost of manufacturing and reduce the use of expensive sealing materials.

The present invention for achieving the above object is a fuel cell cell having a plurality of transfer holes to which a reaction gas is supplied; an assembly guide disposed at both ends of the fuel cell and having concave grooves formed on its upper surface to correspond to the fuel cell; and a first sealing sheet provided with a flexible sheet formed of a sealing material and sealing a space between the fuel cell cell seated in the concave groove and the assembly guide and an upper surface of the assembly guide. An oxide fuel cell is provided.

In addition, it is provided with a flexible sheet formed of a sealing material, characterized in that it further comprises a second sealing sheet for sealing the upper surfaces of both ends of the fuel cell cell seated in the concave groove.

In addition, the lower surface of the assembly guide and the upper surface excluding the concave groove is characterized in that formed in a flat surface.

On the other hand, the present invention is a cell stack in which a plurality of the flat-tubular solid oxide fuel cells are stacked vertically; and a manifold provided at both ends of the cell stack, a receiving groove for accommodating any one of both ends of the cell stack, and a manifold having an exit hole through which the reaction gas enters and exits. A fuel cell stack structure is provided.

Here, the inner surface on which the accommodating groove is formed surrounds both ends of the stacked assembly guides of the cell stack, and the manifold is formed between the accommodating groove and the access hole, and is disposed on the stacked fuel cell cells of the cell stack. It characterized in that it further comprises a connection space for connecting the formed plurality of transfer holes and the entry and exit holes.

The flat tube solid oxide fuel cell and the stack structure using the same according to the present invention increase the safety of the flat tube solid oxide fuel cell stack sealing structure operating at a high temperature, and can reduce the manufacturing cost because it is composed of small standardized parts, and It is possible to reduce the manufacturing cost by reducing the amount of sealing material used.

In addition, the flat tubular solid oxide fuel cell and the stack structure using the same according to the present invention can strengthen the sealing force by combining the cell stack and the manifold, thereby improving durability to increase the lifespan of the cell stack, and efficient fuel A battery system may be provided.

1 is a perspective view of a flat tube type solid oxide fuel cell according to the present invention.
FIG. 2 is a left side view of FIG. 1 ;
3 is a perspective view of a flat tube type solid oxide fuel cell stack structure according to the present invention.
4 is a plan view of a structure of a flat-tubular solid oxide fuel cell stack according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, it should be noted that in adding reference numerals to the components of each drawing, the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, if it is determined that the subject matter of the present invention may be obscured, detailed description thereof will be omitted. In addition, although an embodiment of the present invention will be described below, the technical spirit of the present invention is not limited thereto or may be practiced by those skilled in the art, of course.

1 is a perspective view of a flat tube solid oxide fuel cell according to the present invention, FIG. 2 is a left side view of FIG. 1 , FIG. 3 is a perspective view of a flat tube solid oxide fuel cell stack structure according to the present invention, and FIG. 4 is this view It is a plan view of the structure of a flat-tubular solid oxide fuel cell stack according to the present invention.

Hereinafter, a flat tube type solid oxide fuel cell 1 according to a preferred embodiment of the present invention will be described with reference to FIGS. 1 and 2 .

1 and 2 , the flat tube type solid oxide fuel cell 1 according to the present invention may include a fuel cell 10 , an assembly guide 20 , and a first sealing sheet 30 . .

The fuel cell 10 is formed with a plurality of transfer holes 11 to which the reaction gas is supplied. At this time, a chemical reaction occurs in the fuel cell 10 while the reaction gas is transferred along the plurality of transfer holes 11 , and since the process of generating electricity according to the chemical reaction is well known, a detailed description thereof will be omitted.

The assembly guide 20 is disposed at both ends of the fuel cell 10 , and concave grooves 22 are formed in the upper surface 21 to correspond to the fuel cell 10 .

The assembly guide 20 may be manufactured by machining an insulator that can be used at a high temperature, such as alumina.

In addition, it is preferable that the lower surface 23 of the assembly guide 20 and the upper surface 21 excluding the concave groove 22 are flat so that they can be stacked stably during the configuration of the cell stack 100 to be described later.

As described above, in the present invention, since the processing shape of the assembly guide 20 for configuring the cell stack 100 to be described later is simple, the cost required for processing can be reduced, which is advantageous for mass production.

On the other hand, the first sealing sheet 30 is provided as a flexible sheet formed of a sealing material, the space between the fuel cell 10 seated in the concave groove 22 and the assembly guide 20 and the upper surface of the assembly guide 20 . can be sealed.

The first sealing sheet 30 can be manufactured by cutting a mass-produced sealing material sheet in a straight line, and is easily deformed to correspond to the curved surfaces of the fuel cell 10 and the assembly guide 20 because it is formed of a thin and flexible material. It may be seated between the fuel cell 10 and the assembly guide 20 .

As described above, in the flat tube type solid oxide fuel cell 1 according to the present invention, since the first sealing sheet 30 made of a flexible material is disposed between the fuel cell 10 and the assembly guide 20, it is hermetically sealed. There are advantages to being able to do this.

Meanwhile, the second sealing sheet 40 may be provided as a flexible sheet formed of a sealing material, and may cover the upper surfaces of both ends of the fuel cell 10 seated in the concave groove 22 .

Like the first sealing sheet 30 , the second sealing sheet 40 may be formed of a thin and flexible material.

In this way, the present invention can manufacture the first and second sealing sheets 30 and 40 by cutting the mass-produced sealing material sheet in a straight line, and the shape of the manufactured first and second sealing sheets 30 and 40 Because of this simplicity, the manufacturing process is not complicated, so the cost can be reduced, and compared to the prior art, there is an advantage in that sealing is possible even though the amount of the sealing material input is small.

Meanwhile, the first and second sealing sheets 30 and 40 may be made of a mixture of glass powder, powdery or fibrous oxide, binder, dispersant, plasticizer, solvent, etc., but is not limited thereto, and manufactured in a cutable sheet type It can be formed of various possible sealing materials.

Hereinafter, the flat tube type solid oxide fuel cell stack structure (S) according to the present invention will be described in detail with reference to FIGS. 3 and 4 .

3 and 4 , the flat tubular solid oxide fuel cell stack structure S according to the present invention may include a cell stack 100 and a manifold 200 . Here, the drawings of the first and second sealing sheets 30 and 40 are omitted in FIGS. 3 and 4 for convenience.

Specifically, the cell stack 100 may be configured by stacking a plurality of flat tubular solid oxide fuel cells 1 according to the present invention vertically.

In this case, the number of stacked fuel cells may be variously configured from several to several hundred according to the required output.

As described above, the present invention has the advantage that the cell stack 100 can be manufactured by stacking a plurality of flat tubular solid oxide fuel cells 1 with a simple shape, thereby reducing the number of components required to form the stack. there is.

The manifold 200 is provided at both ends of the cell stack 100 , and a receiving groove 210 in which one of both ends of the cell stack 100 is accommodated is formed. The manifold 200 may be formed of ceramic, but is not limited thereto.

In addition, since the inner surface 211 of the portion in which the receiving groove 210 is formed in the manifold 200 is configured to surround both ends of the stacked assembly guide 20 of the cell stack 100 , gas may leak. It has the advantage of being able to further strengthen the sealing force by being able to block the possible portion with the inner surface 211 of the manifold 200 once more.

On the other hand, the manifold 200 has an entrance hole 220 is formed so that the reactive gas supplied to the stacked fuel cell cells 10 of the cell stack 100 enters and exits, and the receiving groove 210 and the entrance hole ( 220) may be configured to further include a connection space 230 formed between.

Here, the connection space 230 may connect the plurality of transfer holes 11 formed in the stacked fuel cell cells 10 of the cell stack 100 and the access hole 220 .

That is, the plurality of transfer holes 11 of the cell stack 100 accommodated in the receiving groove 210 communicate with the access hole 220 by the connection space 230 and are introduced through the access hole 220 . Gas may be supplied.

In this way, the present invention combines the cell stack 100 and a pair of manifolds 200 , and can supply a reactive gas to the cell stack 100 through the pair of manifolds 200 . By simplifying it, the output can be increased while minimizing the volume.

In addition, the manufacturing cost may be reduced by minimizing the sealing portion between the cell stack 100 and the pair of manifolds 200 , and the loss of reactive gas may be prevented by strengthening the sealing force.

As mentioned above, although preferred embodiments of the present invention have been described in detail, the technical scope of the present invention is not limited to the above-described embodiments and should be interpreted according to the claims. At this time, those skilled in the art should consider that many modifications and variations are possible without departing from the scope of the present invention.

1: flat tube solid oxide fuel cell 10: fuel cell cell
11: a plurality of transfer holes 20: assembly guide
21: upper surface of the assembly guide 22: concave groove
23: lower surface of the assembly guide 30: first sealing sheet
40: second sealing sheet 100: cell stack
200: manifold 210: receiving groove
211: inner surface with receiving groove 220: entrance hole
230: connection space

Claims (5)

a fuel cell in which a plurality of transfer holes to which a reaction gas is supplied are formed;
an assembling guide disposed at both ends of the fuel cell and having concave grooves formed on its upper surface to correspond to the fuel cell; and
A flat tubular solid oxide comprising a first sealing sheet provided with a flexible sheet formed of a sealing material and sealing a space between the fuel cell cell seated in the concave groove and the assembly guide and an upper surface of the assembly guide fuel cell.
The method of claim 1,
The flat tube type solid oxide fuel cell further comprising a second sealing sheet provided with a flexible sheet formed of a sealing material and sealing the upper surfaces of both ends of the fuel cell cell seated in the concave groove.
The method of claim 1,
A flat tube type solid oxide fuel cell, characterized in that the lower surface of the assembly guide and the upper surface excluding the concave groove are formed in a flat surface.
A cell stack in which a plurality of flat tubular solid oxide fuel cells according to any one of claims 1 to 3 are stacked vertically; and
Flat tube solid oxide fuel comprising a manifold provided at both ends of the cell stack, a receiving groove in which either end of the cell stack is accommodated, and an outlet hole through which the reaction gas enters and exits; cell stack structure.
5. The method of claim 4,
The inner surface on which the receiving groove is formed surrounds both ends of the stacked assembly guide of the cell stack,
The manifold is
The flat tube type solid oxide fuel cell, formed between the receiving groove and the access hole, further comprising a connection space connecting the plurality of transfer holes formed in the stacked fuel cell cells of the cell stack and the access hole stack structure.

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