KR20140071078A - Flat Tubular Solid Oxide Fuel Cell Stack - Google Patents

Abstract

The present invention relates to a high temperature flat tubular solid oxide fuel cell stack, which lowers the center of gravity by loading multiple fuel cells along the horizontal direction, and allows to improve the output by uniformly distributing air to the fuel cells via U-shaped fluid paths. The high temperature flat tubular solid oxide fuel cell stack according to the present invention comprises an outer case (11) having an air inlet (19) and an exhaust gas outlet (20); multiple fuel cells (10) loaded within the outer case (11) along the horizontal direction, having multiple fuel transfer holes (10′) and producing electricity by using a chemical reaction of the fuel supplied via the fuel transfer holes (10′); a fuel supply manifold (15) having fuel cells installed on both sides and supplying fuel via the fuel transfer holes (10′); an inner case (13) dividing into a flow path (21) of the air flowed in via the air inlet (19) and a flow path (22) of the exhaust gas completed the reaction in the fuel cells (10), and connected to the exhaust gas outlet (20); a reformer (18) installed near the end of the fuel cells (10), and reforming and supplying the fuel supplied from outside to the fuel supply manifold (15); and a steam generator (12) made of a spiral tube and supplying steam to the reformer (18).

Description

[0001] The present invention relates to a flat tubular solid oxide fuel cell stack,

The present invention relates to a flat-type solid oxide fuel cell stack having a plurality of fuel cells, and more particularly, to a fuel cell stack having a plurality of fuel cells stacked horizontally to reduce the center of gravity thereof, Temperature flattened solid oxide fuel cell stack capable of uniformly distributing power to the cells to improve the output.

A fuel cell means a cell that directly converts chemical energy generated by an oxidation reaction into electric energy. This fuel cell technology is an environmentally friendly future energy technology, because it generates electric energy from materials abundant on the earth, such as hydrogen or oxygen, without using fossil fuels.

The fuel cell stack is composed of a plurality of fuel cell cells, and oxygen is supplied to a cathode, hydrogen is supplied to an anode, and an electrochemical reaction proceeds in the form of an electrolysis reverse reaction of water to generate electricity, heat, and water And it is possible to produce electric energy with high efficiency without causing pollution.

Since the fuel cell stack capable of direct energy conversion is free from the limit of the Carnot Cycle which acts as a limit in the conventional heat pipe, efficiency of 40% or more can be obtained. As the resultant material of the reaction is water, There is no fear, and unlike the conventional heat engine, there is no need to mechanically move parts, so that it is possible to downsize and has various advantages such as no noise. Accordingly, various technologies and researches related to fuel cells are actively proceeding.

In the meantime, the fuel cell stack has been variously classified according to the type of the electrolyte. Among them, a fuel cell stack (PAFC), a molten carbonate fuel cell (MCFC), a solid oxide fuel cell , Solid Oxide Fuel Cell (PEMFC), Polymer Electrolyte Membrane Fuel Cell (DMFC), Direct Methanol Fuel Cell (DMFC), and Alkaline Fuel Cell (AFC) Or planned.

These fuel cells have a wide range of output ranges and applications, and fuel cells suitable for the purpose are selected and used in the demand side of the fuel cell. Particularly, solid oxide fuel cell (SOFC) is relatively easy to control the position of the electrolyte, and the position of the electrolyte is fixed. Therefore, there is no risk of electrolyte depletion and weak corrosion, Power generation, commercial and household use

In the solid oxide fuel cell, when hydrogen is supplied to the anode and hydrogen is supplied to the anode, the solid oxide fuel cell generates a chemical reaction to produce electricity.

The solid oxide fuel cell described above is also used in the form of a single cell. Generally, a plurality of solid oxide fuel cells are stacked in order to increase output. In the case of a stacked type in which a plurality of flat tubular fuel cell units are laminated in this manner, air must be supplied between the fuel cell units while supplying air. However, in order to smoothly supply the air between the fuel cell units, an empty space must be formed between the fuel cell units, thereby reducing the contact area for energizing the fuel cell units. There is a problem that it is not easy.

Particularly, when the fuel cell is formed in a large area, the surface of the fuel cell is often uneven or warped, thereby reducing the contact area for energization and reducing the output.

Accordingly, Korean Patent Laid-Open Publication No. 10-2011-0112512 discloses a flat-tubular solid oxide fuel cell stack in which air is supplied smoothly between fuel cell cells while sufficient electric current is supplied. Further, flat tubular fuel cell stacks are disclosed in Japanese Patent Application Laid-Open No. 2003-282101, Japanese Patent Application Laid-Open No. 2007-035498, and Japanese Laid-Open Patent Application No. 2008-135195.

However, the conventional flat tubular solid oxide fuel cell stack has a problem in that it is unstable due to its high center of gravity as the fuel cell stacks vertically, and air is not evenly distributed to each fuel cell cell, .

JP 2003-282101 A JP 2007-035498 A JP 2008-135195 A KR 10-2011-0022907 A KR 10-2011-0112512 A

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to improve the stability by lowering the height and the center of gravity of the fuel cell stack by stacking the fuel cells in the horizontal direction without stacking them in the vertical direction, The present invention provides a high-temperature flat tubular solid oxide fuel cell stack capable of utilizing an upper space of a solid oxide fuel cell stack.

The present invention also provides a high-temperature flat tubular solid oxide fuel cell stack capable of uniformly distributing air to each fuel cell by allowing air to flow through the U-shaped flow path, The purpose is to provide.

According to an aspect of the present invention, there is provided an air conditioner comprising: an outer case having an air inlet and an exhaust gas outlet; A plurality of fuel cell cells stacked along the horizontal direction in the outer case and formed with a plurality of fuel transfer holes to produce electricity using a chemical reaction of the fuel supplied through the fuel transfer holes; A fuel supply manifold installed on both sides of the fuel cell to supply fuel through the fuel transfer hole; An inner case connected to the exhaust gas outlet and defining a flow passage through which air flows through the air inlet and a flow passage through which the exhaust gas flows in the fuel cell; A reformer installed in the vicinity of an end of the fuel cell to reform the fuel supplied from the outside and supplying the reformed fuel to the fuel supply manifold; And a steam generator formed of a spiral tube and supplying steam to the reformer.

According to the high temperature flat tubular solid oxide fuel cell stack of the present invention, a partition wall is provided at an intermediate portion of the fuel cell so that the air introduced through the air inlet flows along the U-shaped flow path.

In addition, according to the high-temperature flat tubular solid oxide fuel cell stack of the present invention, the partition walls are formed by a comb-like structure in which cell insertion grooves are formed at regular intervals.

According to the high-temperature flat tubular solid oxide fuel cell stack of the present invention, the reformer is formed in a triangular structure and the lower space of the reformer is used as a post-combustion space where unreacted fuel is combusted in the fuel cell .

In addition, according to the high-temperature flat tubular solid oxide fuel cell stack of the present invention, the exhaust gas in the post-combustion space heats the reformer and the steam generator, heats the external inflow air, And is discharged.

In addition, according to the high-temperature flat tubular solid oxide fuel cell stack of the present invention, the heat exchange fins provided in the reformer are protruded to an exhaust gas flow path portion through which the exhaust gas flows in the post combustion space.

In addition, according to the high temperature flat tubular solid oxide fuel cell stack of the present invention, a plurality of hollow tube-shaped connecting members are installed so that air flows in a space between the fuel cell cells.

The high-temperature flat tubular solid oxide fuel cell stack of the present invention can lower the height of the entire system because the fuel cell is stacked along the horizontal direction, and the stability is improved according to the low center of gravity design and the upper space of the system can be utilized for multi- There is an effect to be.

In addition, according to the high-temperature flat tubular solid oxide fuel cell stack of the present invention, since the U-shaped air flow path is formed by the partition walls, the air distributed to each fuel cell is uniformly distributed, The efficiency and the output of the system can be improved, and the system can be downsized.

In addition, according to the high temperature flat tubular solid oxide fuel cell stack of the present invention, since each fuel cell is inserted and fixed in the cell insertion groove formed in the partition wall, the fuel cell can be stably supported, This has a safeguarding effect.

In addition, according to the high-temperature flat tubular solid oxide fuel cell stack of the present invention, as the lower space of the reformer is utilized as a post-combustion space, the reforming reaction of the reformed gas is facilitated and unreacted fuel is burned in the post- Thereby reducing the environmental pollution caused by the water.

1 is a schematic view of a high-temperature flat tubular solid oxide fuel cell stack according to the present invention.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a fuel cell,
3 is a perspective view showing a fuel supply manifold and a fuel cell of the present invention.
4 is a perspective view showing a reformer and a steam generator, which are essential components of the present invention.
5 is a perspective view showing a connecting member as a main component of the present invention.

Hereinafter, a high temperature flat tubular solid oxide fuel cell stack of the present invention will be described with reference to the accompanying drawings.

A high-temperature flat tubular solid oxide fuel cell stack according to the present invention comprises an outer case (11) formed with an air inlet (19) and an exhaust gas outlet (20) and made of a heat insulating material; A plurality of fuel transfer holes 10 'are formed in the outer case 11 along the horizontal direction to generate electricity using the chemical reaction of the fuel supplied through the fuel transfer hole 10' A fuel cell (10); A fuel supply manifold 15 installed at both sides of the fuel cell 10 to supply fuel through the fuel transfer hole 10 '; A flow passage 21 of the air introduced through the air inlet 19 and a flow passage 22 through which the exhaust gas having undergone the reaction in the fuel cell 10 flows are formed in the exhaust gas outlet 20, A connected inner case 13; A reformer (18) installed near the end of the fuel cell (10) to reform the fuel supplied from the outside and supply it to the fuel supply manifold (15); A steam generator 12 formed of a spiral tube and supplying steam to the reformer 18; And a partition wall (16) installed at an intermediate portion of the fuel cell (10) so that the air introduced through the air inlet (19) flows along the U - shaped flow path.

Here, the partition walls 16 are formed in a comb-like structure in which the cell insertion grooves 16 'are formed at regular intervals, and the fuel cell 10 is inserted into the cell insertion grooves 16' Do. As a result, the fuel cell 10 is stably supported and is hardly affected by external vibration.

The reformer 18 is formed in a triangular structure and the lower space of the reformer 18 is used as a post-combustion space where unreacted fuel is combusted in the fuel cell 10. Accordingly, the exhaust gas in the post-combustion space heats the reformer 18 and the steam generator 12, heats the external inflow air, and is discharged to the outside through the exhaust gas outlet 20 .

The reformer 18 may be provided with a heat exchange pin (not shown). It is preferable that the heat exchange fins protrude to a part of the exhaust gas flow path 17 through which the exhaust gas in the post combustion space flows. Accordingly, the heat of the exhaust gas passing through the exhaust gas passage is transferred to the reformer through the heat exchange fin, thereby promoting the reforming reaction.

In addition, as shown in FIG. 5, a plurality of tube-shaped connecting members 14 hollowed out so as to allow air to flow in the space between the fuel cells 10 may be provided.

The high-temperature flat tubular solid oxide fuel cell stack having the above-described structure produces electricity through a plurality of fuel cell cells stacked in the horizontal direction.

Outside air is supplied through the air inlet 19 of the outer case 11 and fuel is supplied to the reformer 18 inside. The reformer 18 reforms the fuel by using a catalyst layer so that a large amount of hydrogen is contained and the reformed fuel is supplied to the fuel supply manifold 15. [

Since a plurality of fuel cell units 10 are connected to both sides of the fuel supply manifold 15, the fuel of the fuel supply manifold 15 is supplied to the fuel cell 10, Is conveyed along the hole 10 '.

The air introduced through the air inlet 19 flows along the flow passage 21 formed between the outer case 11 and the inner case 13 and is supplied with thermal energy. Shaped flow path formed by the partition walls 16 while covering the outside of the fuel cell 10.

Accordingly, ion exchange is performed in the porous layer of the fuel cell 10 contacting with the hydrogen and the external air of the fuel conveyed along the fuel transfer hole 10 'of the fuel cell 10, 10), the electricity is produced. Since the production process of electricity according to the chemical reaction is known, a detailed description thereof will be omitted.

The remaining fuel that has not yet reacted in the fuel cell 10 is discharged to the post combustion space in the lower portion of the reformer 18 through the outlet of the fuel delivery hole 10 ' The residual fuel is burned and the heat generated in the process is supplied to the reformer 18 to promote the reforming reaction.

The exhaust gas after the combustion in the post combustion space flows through the exhaust gas passage 17 formed on the side of the reformer 18 and transfers thermal energy through the heat exchange fins of the reformer 18, Shaped steam generator 12 positioned above the steam generator 18 to generate steam. The steam generated in the steam generator 12 is supplied to the reformer 18 so that the reforming reaction is performed well. The air flows along the flow passage 22 of the exhaust gas formed by the inner case 13, and heats the air introduced from the outside, and is discharged to the outside through the exhaust gas outlet 20.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Changes will be possible.

10 .... fuel cell
10 '... fuel delivery hole
11 ... outer case
12 ... Steam generator
13 ... inner case
14 ... connector
15 ... Fuel supply manifold
16 ... bulkhead
16 '... cell insertion groove
17 ... exhaust gas flow
18 ... reformer
19 ... air inlet
20 ... Exhaust gas outlet
21 ... air flow passage
22 ... exhaust gas flow passage

Claims (7)

An outer case 11 formed with an air inlet 19 and an exhaust gas outlet 20;
A plurality of fuel transfer holes 10 'are formed in the outer case 11 along the horizontal direction to generate electricity using the chemical reaction of the fuel supplied through the fuel transfer hole 10' A fuel cell (10);
A fuel supply manifold 15 installed at both sides of the fuel cell 10 to supply fuel through the fuel transfer hole 10 ';
A flow passage 21 of the air introduced through the air inlet 19 and a flow passage 22 through which the exhaust gas having undergone the reaction in the fuel cell 10 flows are formed in the exhaust gas outlet 20, A connected inner case 13;
A reformer (18) installed near the end of the fuel cell (10) to reform the fuel supplied from the outside and supply it to the fuel supply manifold (15);
And a steam generator (12) made of a spiral tube and supplying steam to the reformer (18). The method according to claim 1,
Wherein a partition wall (16) is provided at an intermediate portion of the fuel cell (10) so that air flowing through the air inlet (19) flows along a U - shaped flow path . 3. The method of claim 2,
Wherein the partition walls (16) are formed in a comb-like structure in which cell insertion grooves (16 ') are formed at regular intervals. The method according to claim 1,
The reformer (18) has a triangular structure, and the lower space of the reformer (18) is used as a post-combustion space where unreacted fuel is combusted in the fuel cell (10) Fuel cell stack. 5. The method of claim 4,
The exhaust gas in the post-combustion space heats the reformer (18) and the steam generator (12), heats the external inflow air, and is discharged to the outside through the exhaust gas outlet (20) Flat tubular solid oxide fuel cell stack. 5. The method of claim 4,
Wherein a heat exchange fin provided in the reformer (18) protrudes into a part of an exhaust gas flow path (17) through which exhaust gas in the post combustion space flows. 7. The method according to any one of claims 1 to 6,
And a plurality of tube-shaped connecting members (14) hollowed out so that air flows in a space between the fuel cells (10).

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