KR101845138B1 - Redox flow battery having enhanced sealing and assembling structure - Google Patents

Abstract

More particularly, the present invention relates to a redox flow cell having improved airtightness and assemblability by improving the assembling structure of a gasket for preventing leakage of an electrolyte solution.
A redox flow cell comprising a cell frame stacked with an ion exchange membrane interposed therebetween to form a unit cell, the redox flow cell comprising a gasket between the cell frame and the ion exchange membrane or between the cell frame and the cell frame, The gasket has a plurality of assembly projections formed in a discontinuous manner on a surface of the gasket which is coupled to the cell frame. The cell frame has a width corresponding to the gasket A guide groove having a height lower than the height of the gasket, and an assembly groove in which the assembly protrusion is inserted in the guide groove.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a redox flow cell having improved airtightness and assemblability,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a redox flow cell, and more particularly, to a gasket assembly structure for preventing leakage of an electrolyte solution.

A redox flow cell is a device that converts the chemical energy of an electrolyte solution into electric energy through a battery cell.

1 is a schematic diagram showing a configuration of a redox flow cell.

As shown in the figure, a redox flow cell stores a positive electrode electrolyte in a positive electrode electrolyte storage tank 210, and a negative electrode electrolyte in a negative electrode electrolyte tank 220.

The positive electrode electrolyte solution and the negative electrode electrolyte stored in the positive electrode electrolyte storage tank 210 and the negative electrode electrolyte tank 220 flow into the positive electrode cell 100A and the negative electrode cell 100B of the cell 100 through the pumps 212 and 222, respectively.

In the anode cell 100A, electrons move through the electrode 150 according to the operation of the power source / load 300, and oxidation / reduction reaction occurs accordingly. Similarly, in the cathode cell 100B, electrons move through the electrode 140 according to the operation of the power source / load 300, so that an oxidation / reduction reaction occurs. After the oxidation / reduction reaction, the cathode electrolyte and the cathode electrolyte are circulated to the anode electrolyte storage tank 210 and the cathode electrolyte storage tank 220.

On the other hand, the anode cell 100A and the cathode cell 100B are separated by the ion exchange membrane 110 through which ions can pass. Accordingly, ion movement, that is, crossover, may occur between the anode cell 100A and the cathode cell 100B. That is, during the charging / discharging process of the redox flow cell, the anolyte ions of the anode cell 100A may move to the cathode cell 100B and the cathode solution ions of the cathode cell 100B may move to the anode cell 100A.

The operating voltage of the battery cell is about 1.0 to 1.7 V and has a relatively low voltage. Therefore, in order to increase the operating voltage, the cells are stacked in series to form a stack. The stack has a structure in which a plurality of battery cells are electrically connected in series and the electrolytes are shared in parallel.

2 is a view showing the structure of a unit cell of a redox flow cell,

2, the unit cell includes an ion exchange membrane 110, a cathode cell frame 120, a cathode cell frame 130, a cathode electrode 140, and an anode electrode 150.

An electrode chamber 128 is formed in the cathode-side cell frame 120 and a cathode electrode 140 is provided in the electrode chamber 128.

The anode side cell frame 130 also has an electrode chamber 138 formed in the same shape as the cathode side frame 120 and the anode chamber 150 is provided in the electrode chamber 138.

The cathode-side cell frame 120 is formed with a cathode electrolyte inlet 122 and a cathode electrolyte outlet 124. The negative electrode electrolyte inlet 122 and the negative electrode electrolyte outlet 124 are connected to a flow path 125 for guiding the electrolyte to the electrodes.

The electrolyte flowing into the cathode electrolyte inlet 122 flows to the cathode electrode 140 along the flow path 125 and the electrolyte solution passing through the cathode electrode 140 flows And then collected through the flow path 125 and flowed to the cathode electrolyte outlet 124.

The positive electrode electrolyte solution is introduced into the positive electrode electrolyte inflow port 132 in the same manner as the positive electrode cell frame 130 and is guided to the positive electrode 150 along the flow path 135. The electrolyte solution passing through the positive electrode 150 again Flows through the flow path 135 and flows to the anode electrolyte discharge port 134. [

Due to such a structure, the cathode electrolyte 140 and the anode electrode 150 disposed between the ion exchange membranes 110 are ion-exchanged while the cathode electrolyte and the anode electrolyte flow respectively. The ion exchange membrane 110 is formed to have a size enough to cover the electrode chambers 128 and 138.

The cathode side cell frame 120 and the anode side cell frame 130 are made of a synthetic resin material having an acid resistance and can be formed by disposing cell frames having the same shape in opposite directions to each other.

Although not shown in the drawing, a gasket is provided as a sealing means between the cell frame and the ion exchange membrane. The gasket is arranged to surround the electrode chamber to prevent leakage of the electrolyte solution.

When the cell stack is assembled, the cell frame is assembled by sequentially stacking the ion exchange membrane and the cell frame in a state that the plate surface is horizontal.

If the gasket can not be assembled in the correct position during the assembling process, there is a problem that the electrolyte leaks.

An object of the present invention is to improve the assemblability of the stack by allowing the gasket to be fixed in a fixed position in the stack assembly of the redox flow cell.

Another object of the present invention is to improve the airtightness of the redox flow cell by allowing the gasket to be uniformly compressed as a whole during assembly of the stack.

A redox flow cell comprising a cell frame stacked with an ion exchange membrane interposed therebetween to form a unit cell, the redox flow cell comprising a gasket between the cell frame and the ion exchange membrane or between the cell frame and the cell frame, The gasket has a plurality of assembly projections formed in a discontinuous manner on a surface of the gasket which is coupled to the cell frame. The cell frame has a width corresponding to the gasket A guide groove having a height lower than the height of the gasket and an assembly groove in which the assembly protrusion is inserted, the depth of the guide groove being 30% to 80% of the depth of the assembly groove Lt; RTI ID = 0.0 > cell < / RTI >

In another embodiment, the gasket may have an assembling groove, and the assembling protrusion may be provided in the guide groove.

At this time, it is preferable that the height of the assembling protrusion is in the range of 50% to 90% of the thickness of the gasket, and the depth of the assembling groove is in the range of 50% to 90% of the thickness of the gasket.

Preferably, the depth of the mounting groove ranges from 105 to 150% of the height of the mounting projection,

It is further preferable that the horizontal cross-sectional area of the mounting groove is formed smaller than the horizontal cross-sectional area of the mounting projection.

In this case, the assembling protrusion may be formed in a circular shape with a horizontal cross section, and the horizontal cross section of the assembling groove may be formed into an elliptical shape having a long radius equal to the radius of the assembling protrusion.

It is preferable that the gasket has a shape in which a curved section and a straight section are mixed, and the assembling projection or the assembling groove is provided in the switching section between the straight section and the curved section,

It is preferable that the gasket has an assembling projection or an assembling groove in a portion equalizing the straight line section.

The thickness of the gasket is preferably in the range of 120 to 170% of the depth of the guide groove.

In the redox flow cell according to the present invention, the gasket is fixed in a state of being assembled to the cell frame, so that the gasket is maintained in a fixed position during the stacking operation of the cell stack. Even if the gasket is placed downward in the gravity direction, This effect is not separated from the cell frame.

In the redox flow cell according to the present invention, since the compressed surface of the gasket maintains a uniform width when the gasket is assembled to the cell frame, when the cell stack is assembled and the tightening pressure is applied, the gasket is uniformly compressed Effect.

1 is a schematic diagram showing a configuration of a redox flow cell.
2 is a block diagram showing the structure of a unit cell of a redox flow cell.
3 is a view showing the structure of a unit cell of a redox flow cell according to the present invention.
4 is an enlarged view of a guide groove and a gasket of a cell frame of a redox flow cell according to an embodiment of the present invention.
5 is a rear perspective view illustrating an electrode thread gasket of a redox flow cell according to the present invention.
6 is a cross-sectional view of a redox flow cell according to the present invention in a state where a cell frame and a gasket are assembled together.
7 is an enlarged view of a guide groove and a gasket of a cell frame of a redox flow cell according to another embodiment of the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or preliminary meaning and the inventor shall properly define the concept of the term in order to describe its invention in the best possible way It should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention. It should be noted that the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention, It should be understood that various equivalents and modifications are possible.

3 is a view showing the structure of a unit cell of a redox flow cell according to the present invention.

As shown in the figure, the unit cells of the redox flow cell are stacked with the cell frames 120 and 130 with the ion exchange membrane 110 interposed therebetween. At this time, one cell frame becomes the anode side cell frame 130 and the other one cell frame becomes the cathode side cell frame 120.

The anode side cell frame and the cathode side cell frame are determined in accordance with the type of the electrolytic solution flowing, and the shape and structure are substantially the same. Hereinafter, the anode-side cell frame and the cathode-side cell frame are collectively referred to as a cell frame, not separately.

Electrode chambers 128 and 138 are provided in the cell frames 120 and 130 and electrodes 140 and 150 are disposed in the electrode chambers 128 and 138. The electrodes 140 and 150 are made of a hydroelectric material having conductivity, and carbon felt or the like can be used as an electrode.

The portions to which the gaskets 162a, 162b, 164a, and 164b are applied in the laminated structure of the unit cells are between the electrode chambers 128 and 138 and the ion exchange membrane 110 and between the through-flow passages 122, 124, 132,

The electrode thread gaskets 162a and 162b surrounding the electrode chambers 128 and 138 are provided so that the electrolyte solution flowing through the electrode chambers 128 and 138 is not leaked to the portion contacting the ion exchange membrane 110, Respectively, so as to seal between the gaskets 164a and 164b.

In actual assembly of the stack, the cell frame 130 is placed, the gaskets 162b and 164b are disposed thereon, the ion exchange membrane 110 is disposed thereon, and the gaskets 162a and 164a And the cell frame 120 are stacked.

If the gasket is not fixed to the cell frame 120 above the cell frame 120 at the time of laminating the cell frame 120 above the ion exchange membrane 110, the position of the gasket may be misaligned, If the position is wrong, there is a problem that the seal does not work properly.

In order to prevent such a problem, a method of adhering a gasket to a cell frame has been used. However, a bonding process using an adhesive is added, which makes the operation troublesome. Also, when the adhesive is excessively applied, the elasticity of the gasket may be lowered, which may cause a problem in sealing performance.

The present invention provides a structure in which the gasket can be fixed to the cell frame without using a separate adhesive by providing a structure in which the gasket can be assembled at the correct position of the cell frame.

To this end, the present invention is provided with guide grooves 137, 139 for preventing the gasket from deviating from the correct position in the cell frame. The guide grooves 137 and 139 are formed in the shape of a concave groove at a position where the gasket is to be disposed on the cell frame so that a part of the gasket is accommodated in the guide grooves 137 and 139, thereby restricting the horizontal position of the gasket .

4 is an enlarged view of a guide groove and a gasket of a cell frame of a redox flow cell according to an embodiment of the present invention.

The gasket 162 according to the present invention has a band shape having a constant width w and a thickness h1 and includes a plurality of assembly projections 163 formed discontinuously on a surface coupled to the cell frame, Respectively.

The assembling protrusion 163 is formed of the same material as the gasket, and is formed integrally with the gasket. Such a gasket can be produced by a method of injection molding.

The cell frame 130 has a guide groove 139 having a width w corresponding to the gasket at a position of the gasket and having a height h2 lower than the height of the gasket.

So that a part of the gasket is fitted in the guide groove 139 so that the gasket 162 can be fixed at the correct position of the cell frame 130.

The guide groove 139 prevents the gasket 162 from deviating in the horizontal direction and does not provide a fixing force for preventing vertical deviation. The fixing force for preventing the deviation in the vertical direction is generated by a fitting defect of the assembling protrusion 163 of the assembly groove 139a and the gasket 162 to be described later.

The width of the gasket 163 is preferably set to 2 mm or more. The width of the gasket is directly related to the sealing performance. For securing the sealing performance, the width of the gasket 163 is 2 mm or more. When the width of the gasket 163 is increased, the clamping pressure for compressing the gasket 163 must be increased and the size of the cell frame must be increased due to the increase of the area occupied by the gasket 163. Therefore, It is preferable to set the maximum width to 10 mm or less in consideration of this point.

The thickness of the gasket 162 is determined by the depth h2 of the guide groove 139. The thickness of the gasket 162 is the thickness of the portion where the assembling protrusion 163 is not formed.

It is preferable that the compression ratio of the gasket 162 is set to be 20 to 40% when the gasket 162 is completely compressed into the guide groove 139.

In other words, the thickness h1 of the gasket 162 preferably ranges from 120% to 170% of the depth h2 of the guide groove 139.

If the compression ratio of the gasket is less than 20%, there is a problem that the sealing performance is deteriorated, and a compression ratio of 40% or more is not preferable because the tightening pressure must increase.

The depth h2 of the guide groove 139 is preferably set to 0.5 mm or more. The depth h2 of the guide groove 139 is used to fix the gasket 162 to the precise position of the cell frame. When the depth h2 of the guide groove 139 is less than 0.5 mm, 162 may not be seated in the correct position.

As the depth h2 of the guide groove 139 becomes deeper, the thickness of the cell frame becomes thinner at the portion where the guide groove 139 is formed, so that it is preferable that the height is set at a level at which the strength of the cell frame is not lowered , And 2.0 mm or less.

The assembly groove 139a is formed deep inside the guide groove 139 in the depth direction of the guide groove 139. The assembly groove 139a is disposed at a position corresponding to the assembly protrusion 163 of the gasket 162 inside the guide groove 139. [

The horizontal cross-sectional area of the assembly groove 139a is formed to be narrower than the horizontal cross-sectional area of the assembly protrusion 163 of the gasket 162. [ This is because the assembling protrusion 163 is horizontally compressed when the assembling protrusion 163 is inserted into the assembling recess 139a so that the assembling protrusion 163 can be fixed to the assembling recess 139a due to the frictional force generated by the compression .

As shown in the figure, when the horizontal cross section of the assembly projections 163 is circular, the horizontal cross section of the assembly groove 139a may be formed in an elliptical shape having a smaller area than the circular shape. At this time, the elliptical long radius, which is the cross-sectional shape of the assembly groove 139a, can be formed to be equal to the radius of the circular cross section of the assembling projection 163. This shape is for compressing the assembly projections 163 only in one direction when the assembly projections 163 are fitted into the assembly grooves 139a, thereby allowing the assembly projections 163 to be smoothly inserted.

Of course, the horizontal cross section of the assembling protrusion 163 and the assembling groove 139a may be formed in a polygonal shape. For example, when the horizontal cross section of the assembly projections 163 is formed into a square shape, the horizontal cross section of the assembly groove 139a can be formed into a rectangular shape.

The height of the assembling protrusion 163 is preferably set in a range of 50 to 90% of the thickness of the gasket.

When the height of the assembling protrusion 163 is set to less than 50% of the thickness of the gasket, the assembling protrusion 163 becomes insufficient in fixing the gasket to the assembling recess 139a, The height of the projecting portion of the gasket exceeds 90% of the thickness of the gasket, the depth of the assembling groove 139a must be ensured so that the thickness of the frame is increased, which is unnecessary. That is, since the frame thickness at the portion where the mounting groove is formed becomes too thin, there is a possibility that the possibility of breakage of the frame, which normally receives a load of 1 ton or more, may increase.

The depth of the assembly groove 139a may be the same as the height of the assembly protrusion 163 or may be deeper than the height of the assembly protrusion 163. This is to ensure that the assembling protrusion 163 is completely inserted into the mounting groove 139a,

The depth of the assembly groove 139a is preferably set to 1.05 to 1.50 times the height of the assembly protrusion 163. [ The depth of the assembly groove must be greater than the height of the assembly protrusion because the assembly protrusion 163 is extruded in the horizontal direction inside the assembly groove 139a so that the volume change in the vertical direction can be absorbed by the assembly groove will be. If the assembly groove 139a exceeds 1.5 times, the thickness of the cell frame at the portion where the assembly groove 139a is formed becomes too thin, so that the strength of the cell frame is lowered. 163), a part of the assembling protrusion is not inserted into the assembling groove 100% due to a change in the volume of the assembling protrusion inserted in the assembling groove 139a in the vertical direction, so that the gasket is lifted from the cell frame, There arises a problem that a clearance is generated between the bottom surface (the portion where the assembling protrusion is not formed) and the guide groove of the cell frame.

5 is a rear perspective view illustrating an electrode thread gasket of a redox flow cell according to the present invention.

As shown in the figure, the electrode thread gasket 163 is formed to surround the periphery of the electrode chamber and may be formed into a square (rounded rectangle) shape formed as a curved line at an edge.

When the gasket has a shape in which the straight section and the curved section are mixed, it is preferable that the assembly projection 163 is provided at the switching section between the straight section and the curved section.

In other words, it is preferable to provide the assembly projections 163 at both ends of the curved section. Since the curved section is not easily fixed to the straight section, the assembling projection 163 is provided at the beginning and the end of the curved section so that the curved section can be fixed at the correct position.

Also, in the case of the straight line section, it is preferable that the assembly projections 163 are provided at a constant interval or in a portion equalizing the entire straight line section. If the straight section is long, the gasket may be sagged at that part, so that it can be fixed by the assembly projections 163 at regular intervals.

6 is a cross-sectional view of a redox flow cell according to the present invention in a state where a cell frame and a gasket are assembled together.

When the gasket 162 is assembled to the guide groove 139 of the cell frame, the assembly protrusion 163 of the gasket 162 is inserted into the assembly groove 139a formed in the guide groove . At this time, the assembling protrusion 163 receives a compressive force in the horizontal direction. As described above, the depth of the assembly groove is 1.05 to 1.5 times the height of the assembly projection, but assuming that the assembly projection is inserted into the assembly groove and the assembly protrusion is increased in volume in the vertical direction to be 100% filled in the assembly groove Respectively. However, even if the assembly projections do not completely fill the lower part of the assembly groove, sufficient engaging force (frictional force) can be obtained if all of the assembly projections are inserted into the assembly groove.

In this assembled state, the gasket 162 (that is, the gasket portion excluding the assembling protrusion) located inside the guide groove 139 is in a state in which it is not subjected to the compressive force, so that a flat surface can be maintained. Therefore, it can be uniformly compressed as a whole when brought into contact with the ion exchange membrane, thereby exhibiting an excellent sealing effect.

Particularly, the depth h3 of the guide groove and the depth h2 of the assembly groove exist in the frame structure of the present invention, and two recesses exist. The depth h3 of the guide groove is equal to the depth h3 of the depth It is preferable to have a range of 30% to 80%. When the depth of the guide groove is 30% or less of the depth of the mounting groove, the mounting groove becomes too shallow and the bonding force with the mounting projection is insufficient. When the depth is 80% or more, the thickness of the frame itself is reduced by the guide groove and the mounting groove There is a problem that the strength is extremely reduced.

7 is an enlarged view of a guide groove and a gasket of a cell frame of a redox flow cell according to another embodiment of the present invention.

In the illustrated embodiment, an assembly groove 163-1 is formed in the gasket 162, and an assembly protrusion 139a-1 is formed in the guide groove 139. FIG.

The gasket 162 is provided with an assembly groove 163-1 instead of the assembly protrusion and the assembly groove 139a-1 is formed in the guide groove 139 instead of the assembly protrusion. So that redundant description is omitted.

It is to be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive, and the scope of the present invention will be indicated by the appended claims rather than by the foregoing detailed description. It is intended that all changes and modifications that come within the meaning and range of equivalency of the claims, as well as any equivalents thereof, be within the scope of the present invention.

110: ion exchange membrane
120, 130: cell frame
140, 150: electrode
122, 124, 132, 134:
137, 139: Guide groove
139a, 163-1: Assembly groove
162, 162a, 162b, 164a, 164b:
163, 139a-1: Assembly projections

Claims (12)

In a redox flow cell constituting a unit cell in which cell frames are stacked with an ion exchange membrane interposed therebetween,
A gasket is provided between the cell frame and the ion exchange membrane or between the cell frame and the cell frame,
Wherein the gasket has a strip shape having a predetermined width and height and includes a plurality of assembly projections formed discontinuously on a surface of the gasket coupled to the cell frame,
Wherein the cell frame has a guide groove having a width corresponding to the gasket at an arrangement position of the gasket and a height lower than a height of the gasket and an assembly groove in which the assembly protrusion is inserted,
Wherein the horizontal cross-sectional area of the mounting groove is smaller than the horizontal cross-
Redox flow cell.
In a redox flow cell constituting a unit cell in which cell frames are stacked with an ion exchange membrane interposed therebetween,
A gasket is provided between the cell frame and the ion exchange membrane or between the cell frame and the cell frame,
The gasket has a band shape having a predetermined width and height and includes a plurality of assembly grooves formed discontinuously on a surface of the gasket coupled to the cell frame,
Wherein the cell frame has a guide groove having a width corresponding to the gasket at an arrangement position of the gasket and a height lower than a height of the gasket and an assembling protrusion that is inserted into the assembly groove in the guide groove,
Wherein the horizontal cross-sectional area of the mounting groove is smaller than the horizontal cross-
Redox flow cell.
The method according to claim 1,
Wherein the height of the assembly protrusion ranges from 50% to 90% of the thickness of the gasket.
3. The method of claim 2,
Wherein the depth of the assembly groove ranges from 50% to 90% of the thickness of the gasket.
3. The method according to claim 1 or 2,
Wherein the depth of the assembly groove is in the range of 105 to 150% of the height of the assembly protrusion.
delete 3. The method according to claim 1 or 2,
Wherein the assembling protrusion has a circular cross section,
Wherein the horizontal cross-section of the assembly groove is formed in an elliptical shape having a long radius equal to a radius of the assembly protrusion.
The method according to claim 1,
The gasket has a shape in which a curved section and a straight section are mixed,
Wherein the redox flow cell is provided with an assembly protrusion at the switching section between the straight line section and the curved section.
9. The method of claim 8,
Wherein the gasket has an assembly protrusion at a portion equalizing the straight line section.
3. The method of claim 2,
The gasket has a shape in which a curved section and a straight section are mixed,
Wherein the redox flow cell is provided with an assembly groove in the switching section between the straight section and the curved section.
11. The method of claim 10,
Wherein the gasket has an assembling groove at a portion equalizing the straight line section.
6. The method of claim 5,
Wherein the thickness of the gasket is in the range of 120 to 170% of the depth of the guide groove.

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