KR101180228B1 - Sealant for planar solid oxide fuel cell and sealing method using the same - Google Patents

Abstract

The present invention relates to a sealant for a plate-type solid oxide fuel cell and a sealing method using the same, and more particularly, to a plate-type solid oxide fuel cell sealant capable of reducing materials lost by using a block-type seal that can be assembled. It relates to the sealing method used.
The present invention provides a sealing material for a flat plate type solid oxide fuel cell and a sealing method using the same, wherein at least one block unit forming a closed loop is assembled.
According to the present invention, by using a block-type seal that can be assembled, it is possible to reduce the material lost while at the same time ensuring the sealing property of the gas is effective in reducing the cost, can be easily applied to a large size sealing structure, stack stability Can also contribute.

Description

Sealant for flat solid oxide fuel cell and sealing method using the same {SEALANT FOR PLANAR SOLID OXIDE FUEL CELL AND SEALING METHOD USING THE SAME}

The present invention relates to a sealant for a plate-type solid oxide fuel cell and a sealing method using the same, and more particularly, to a plate-type solid oxide fuel cell sealant capable of reducing materials lost by using a block-type seal that can be assembled. It relates to the sealing method used.

Solid oxide fuel cells generally operate at the highest temperatures (700 to 1000 ° C) of fuel cells, and are simpler in structure than other fuel cells because all components are solid, and the loss and replacement of electrolytes and corrosion There is no problem, no noble metal catalysts and easy fuel supply through direct internal reforming. In addition, it has the advantage that thermal combined cycle power generation using waste heat is possible because the high-temperature gas is discharged. Because of these advantages, research on solid oxide fuel cells is being actively conducted.

A solid oxide fuel cell (SOFC) is an electrochemical energy conversion device, and is composed of an oxygen ion conductive electrolyte and an air electrode (anode) and a fuel electrode (cathode) located on both sides thereof. In the cathode, oxygen ions generated by the reduction reaction of oxygen move to the anode through the electrolyte and react with hydrogen supplied to the anode again to generate water. At this time, electrons are generated at the anode and electrons are consumed at the cathode. When the electrodes are connected to each other, electricity flows.

However, since the power generated from one unit cell based on the air electrode, the electrolyte and the fuel electrode is very small, a large amount of power can be output by stacking (stacking) several unit cells to form a fuel cell. It can be applied to various power generation system fields. For the stacking, the cathode of one unit cell and the anode of another unit cell need to be electrically connected, and a separator is used for this purpose. In addition, a current collector is provided between the cathode or the anode and the separator to allow the cathode or the anode to be in uniform electrical contact with the separator. As the current collector, a ceramic material or silver or platinum may be used.

In addition, a sealing material is used so that the fuel gas supplied to the anode and the air supplied to the cathode are not mixed with each other. In order to seal the flat fuel cell, a sealing sheet is produced and laminated, and then the integrated laminate There is a method of cutting out the structure of the sealing portion. Such a method can secure a uniform thickness, and the structure of the cut seal is very uniform. However, the portions other than the seals are punched out and discarded, so the material cost is greatly increased. In particular, since the area in which the sealant is used is very small, the loss material cost increases as the cross section of the fuel cell becomes larger, and it is difficult to secure the thickness uniformity in the sheet because the sealant sheet must also be manufactured in a large area.

Another method for sealing is to prepare a sealant paste and dispense only the part to be sealed. Since the method uses the material only in the portion that needs to be sealed, there is an advantage of the material cost, but after dispensing, the thickness is not uniform and the cross-sectional shape does not form a right angle, resulting in nonuniformity in stack mounting.

An object of the present invention is to provide a sealing material for a plate-type solid oxide fuel cell and a sealing method using the same, which can reduce the material lost while at the same time securing the sealing property of the gas by using a block-type seal that can be assembled.

The present invention provides a sealant for a plate-type solid oxide fuel cell, characterized in that at least one block unit forming a closed loop is assembled.

Each of the block units includes one inner member and two outer members, and one end of each of the two outer members is connected to each other, and the inner member forms the gas flow path together with the two outer members. It is connected to the two outer members, the other end of the two outer member is extended than the portion connected to the inner member, the other end of the extended one outer member has a fastening projection, the other of the outer member It is preferable that the other end has a fastening groove.

It is preferable that the coupling groove of the block unit is assembled with the coupling protrusion of another block unit.

The sealing material is composed of four block units, preferably having a rectangular shape.

The sealing material may further include a connection unit for connecting the block unit, one side of the connection unit is formed with a fastening protrusion, it is preferable that the fastening groove is formed on the opposite side.

The present invention comprises the steps of preparing a sheet for sealing material; Manufacturing a block unit by punching the sheet for sealing material; Assembling the manufactured block unit to manufacture a sealing material; Mounting the manufactured sealant on a fuel cell; And melt-pressing the fuel cell equipped with the sealing material.

In the punching, the block unit includes one inner member and two outer members, respectively, one end of each of the two outer members is connected to each other, and the inner member is closed with the two outer members. It is connected with the two outer member to form a, the other end of the two outer member is extended than the portion connected with the inner member, the other end of the one extended outer member has a fastening protrusion, the other The other end of the outer member of the is preferably done to have a fastening groove.

The assembling step is preferably performed so that the fastening groove of the block unit is coupled to the fastening protrusion of the other block unit.

The sealing method further includes the step of punching the sheet for sealing material to produce a connection unit, it is preferable to produce a sealing material by assembling between the block units through the connection unit in the sealing material manufacturing step.

The connecting unit manufacturing step is preferably performed so that the fastening protrusion is formed on one side of the connection unit, the fastening groove is formed on the opposite side.

It is preferable that the said melting temperature is 800-850 degreeC, and it is preferable that the said crimping | compression uses a hydraulic pressure or a cylinder.

According to the present invention, by using a block-type seal that can be assembled, it is possible to reduce the material lost while at the same time ensuring the sealing property of the gas is effective in reducing the cost, can be easily applied to a large size sealing structure, stack stability Can also contribute.

1 is a cross-sectional view showing an example of a sealing material form.
2 is a cross-sectional view showing an example of a sealing material according to the present invention.
3 is a cross-sectional view showing an example of a sealing material including a block unit and a connection unit.
4 is a cross-sectional view illustrating various forms of a block unit and a connection unit.

Conventionally, in order to manufacture a sealing material for a flat fuel cell, a method of manufacturing a sealing material sheet and then cutting the structure of the required sealing part is used. 1 is a cross-sectional view showing an example of the shape of the sealing material, punching is used to manufacture the sealing material 1 having the form of FIG. 1, and the other sealing materials except the shape of the sealing material have a disadvantage in that they are discarded.

In order to solve this problem, the components of the sealant are manufactured in the form of a unit block to reduce materials that are lost, and the seals are manufactured by assembling the seal of the unit block form, thereby ensuring gas sealing property. An object of the present invention is to provide a sealant for a flat solid oxide fuel cell.

2 is a cross-sectional view showing an example of a sealing material according to the present invention. As shown in FIG. 2, the block unit 10, which is a sealing unit, may have a form of a unit block having a closed loop, and at least one or more may be assembled to form a sealing material for a solid oxide fuel cell. This can reduce the loss of materials that are unnecessarily discarded, thereby reducing the manufacturing cost.

In this case, the block unit 10 includes one inner member 11 and two outer members 12a and 12b, respectively, and one end of each of the two outer members 12a and 12b is connected to each other. The inner member 11 is connected to the two outer members 12a and 12b to form a gas flow path together with the two outer members, and the other ends of the two outer members 12a and 12b are inner members. 11, the other end 13a of the extended one outer member 12a has a fastening protrusion 14 and the other end (1) of the other outer member 12b. 13b) preferably has a fastening groove 15.

The fastening groove 15 of the block unit 10 is preferably assembled to be combined with the fastening protrusion 24 of the other block unit 20. In this case, the coupling force of the block unit is stronger than when assembled without the protrusion and the fastening groove, thereby improving the gas sealing property.

The sealing material is composed of four block units 10, it is preferable to have a rectangular shape, through which it is possible to increase the effect of the sealing by being applied to each corner of the fuel cell having a rectangular cross section.

3 is a cross-sectional view showing an example of a sealing material including a block unit 10 and a connection unit 100. As shown in FIG. 3, the sealant of the present invention may further include a connection unit 100 for connecting the block units 10 and 20. The size, shape, and number of the connection units 100 may be variously changed according to the shape of the fuel cell.

However, as shown in FIG. 3, when the block unit 10 has the fastening protrusion 14 and the fastening groove 15, for easy assembly, a fastening protrusion 114 is formed at one side of the connection unit 100. It is preferable that the fastening groove 115 is formed on the opposite side of the one side.

4 is a cross-sectional view illustrating various forms of a block unit and a connection unit. As shown in (a), as described above, the block unit 30 and the connection unit 130 have the fastening protrusions 34 and 134 and the fastening grooves 35 and 150, respectively. (b) the block unit 40 has only the fastening protrusions 44, the connection unit 140 is a form having only the fastening groove 145. (c) the block unit 50 has a fastening groove 55 only, the connection unit 150 is a form having a fastening protrusion 154 only. As such, the block unit and the connection unit may have various forms. In addition, the fastening protrusion and the fastening groove may also be easily changed in various forms. However, in order to further suppress the material lost, it is preferable to adopt the block unit and the connection unit of the form (a).

As a component of the above-mentioned sealing material, it is preferable that some ceramics are contained in a glass material or the said glass material.

Hereinafter, the manufacturing method of this invention is demonstrated.

First, after preparing the sealing material sheet, the sealing sheet is punched to produce a block unit.

In the punching, the block unit includes one inner member and two outer members, respectively, one end of each of the two outer members is connected to each other, and the inner member forms a closed loop together with the two outer members. It is connected to each other end of the two outer member to form, the other end of the two outer member is extended than the portion that is connected to the inner member, the other end of the extended one outer member is fastening projections It is preferable that the other end of the other outer member has a fastening groove.

At this time, it may further comprise the step of manufacturing a connection unit by punching the sheet for sealing material, it is preferable to punch so that the fastening projection is formed on one side of the connection unit, the fastening groove is formed on the opposite side of the one side. .

Thereafter, the prepared block unit is assembled to manufacture a sealing material. At this time, it is preferable that the fastening groove of the block unit is coupled to the fastening protrusion of another block unit. Of course, the sealing unit may be manufactured by further including the connection unit prepared as described above.

Thereafter, the manufactured sealant is mounted on the fuel cell, or the fuel cell equipped with the sealant is melt-pressed. It is preferable that the melting temperature is 800 to 850 ° C. When the melt compression treatment is performed at a temperature in the above range, the melt compression is effective, and it is easy to maintain the shape of the sealing material and further, the shape of the fuel cell. The pressing may use a hydraulic pressure or a cylinder.

1: sealant 10: block unit
11: inner member 12: outer member
13: outer member end 14: fastening protrusion
15: fastening groove 20: block unit
24: fastening protrusion

Claims (13)

Sealing material for a flat plate type solid oxide fuel cell, characterized in that at least one block unit forming a closed loop is assembled.
The apparatus of claim 1, wherein each of the block units includes one inner member and two outer members, one end of each of the two outer members being connected to each other, and the inner member is joined together with the two outer members. It is connected to the two outer members to form a gas flow path, the other end of the two outer member is extended than the portion connected to the inner member, the other end of the one extended outer member has a fastening protrusion, Sealing material for a flat solid oxide fuel cell, characterized in that the other end of the other outer member has a fastening groove.
The sealant of claim 2, wherein the fastening groove of the block unit is assembled with the fastening protrusion of another block unit.
4. The sealing material for a solid oxide fuel cell as claimed in claim 3, wherein the sealing material is formed of four block units and has a rectangular shape.
The sealing material for solid oxide fuel cell according to any one of claims 1 to 4, wherein the sealing material further comprises a connecting unit for connecting the block unit.
The sealing material for a solid oxide fuel cell as claimed in claim 5, wherein a fastening protrusion is formed at one side of the connection unit, and a fastening groove is formed at the opposite side.
Preparing a sheet for sealing material;
Manufacturing a block unit by punching the sheet for sealing material;
Assembling the manufactured block unit to manufacture a sealing material;
Mounting the manufactured sealant on a fuel cell; And
And sealing the fuel cell equipped with the sealing material by melt compression.
8. The method of claim 7, wherein the punching block unit comprises one inner member and two outer members, one end of each of the two outer members are connected to each other, the inner member is the two outer It is connected with the two outer member to form a closed loop with the member, the other end of the two outer member is extended than the portion connected with the inner member, the other end of the one extended outer member is a fastening protrusion And the other end of the other outer member is provided with a fastening groove.
8. The method of claim 7, wherein the assembling step is performed such that the fastening groove of the block unit is coupled to the fastening protrusion of another block unit.
The method of claim 7, wherein the sealing method further comprises the step of manufacturing a connecting unit by punching the sheet for the sealing material, in the manufacturing step of the sealing material through the connecting unit between the block units to form a flat solid oxide Sealing method of fuel cell.
The method of claim 10, wherein the connecting unit manufacturing step is performed such that a fastening protrusion is formed at one side of the connection unit, and a fastening groove is formed at the opposite side.
8. The method of claim 7, wherein the melting temperature is 800 to 850 ° C.
8. The method of claim 7, wherein the pressing uses a hydraulic pressure or a cylinder.

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