KR101555651B1 - Redox flow battery with gasket - Google Patents

Abstract

Provided is a redox flow cell capable of suppressing deformation of a gasket to increase airtightness of a stack and effectively prevent leakage of an electrolyte solution. The redox flow cell comprises first and second porous electrodes positioned across the membrane, first and second porous electrodes positioned at the edges of each of the first and second porous electrodes and for fixing the first and second porous electrodes, And a plurality of gaskets arranged in close contact with the first and second flow frames to prevent leakage of the electrolyte solution, . At least one gasket of the plurality of gaskets forms a continuous protrusion on one surface.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a redox flow battery with a gasket,

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

Recently, as new and renewable energy technologies such as photovoltaic power generation and wind power generation are developed, demand for large capacity power storage devices is increasing. The electric power storage device stores electric energy when the power generation amount is high, and releases the electric energy when the consumption amount is large, thereby solving the problem of the inconsistency between the power generation volatility and the supply time point.

The redox (redox) flow cell is a secondary battery for large capacity power storage. It has low maintenance cost, operates at room temperature, and capacity and output can be designed independently. The redox flow battery includes a stack in which a plurality of battery cells are stacked, a tank for storing a positive electrode electrolyte solution and a negative electrode electrolyte solution, and a pump for supplying and discharging the positive electrode electrolyte solution and the negative electrode electrolyte solution as a stack.

During the charging / discharging process, the electrolyte circulates inside the stack, so that the stack must have a hermetical structure to prevent leakage of the electrolyte. When the parts constituting the stack are made of the same material, the deposition technique can be applied. However, when the porous electrode made of sponge type carbon felt such as vanadium redox flow cell is included, deposition is difficult. Therefore, .

However, since the conventional gasket is easily deformed in the process of pressing the stack at a high pressure, the airtightness of the stack is lowered and it is not effective in preventing leakage. In addition, if the gasket is deformed too much, the entire stack may be distorted. Thus, conventional gaskets cause the durability and performance of the stack to deteriorate in actual application.

Disclosed is a redox flow cell capable of suppressing deformation of a gasket to increase the airtightness of the stack, prevent electrolyte leakage, and improve durability and charge / discharge performance of the stack.

The redox flow cell according to an embodiment of the present invention includes first and second porous electrodes positioned with a membrane therebetween, and first and second porous electrodes positioned at the edges of the first and second porous electrodes, respectively, The first flow frame and the second flow frame; an anode electrode which is in close contact with the outside of the first porous electrode; a cathode electrode which is in close contact with the outside of the second porous electrode; And a plurality of gaskets for preventing leakage. At least one gasket of the plurality of gaskets forms a continuous protrusion on one surface.

The plurality of gaskets include a pair of face gaskets positioned between the first and second flow frames and the membrane, wherein each of the pair of face gaskets forms a first projection on the face facing the membrane, As shown in Fig.

Each of the pair of face gaskets forms a central opening for the first or second porous electrode arrangement, and the first projection may be formed to surround the central opening at a predetermined distance from the central opening. Each of the pair of face gaskets forms four electrolyte through holes for electrolytic solution circulation and can form o-ring protrusions around at least two electrolyte through holes among the four electrolyte through holes.

Each of the pair of face gaskets can be made of fluorocarbon rubber and can form at least one expansion accommodating portion that accommodates sideways volumetric expansion by the tightening pressure.

The first flow frame and the second flow frame form a plurality of flow passages for supplying and discharging the electrolyte. Each of the pair of face gaskets forms a first expansion accommodating portion in a region facing the plurality of flow passages, The second expansion accommodating portion can be formed.

The plurality of gaskets include a pair of band gaskets positioned between the first flow frame and the anode electrode and between the second flow frame and the cathode electrode, and each of the pair of band gaskets is provided on the surface facing the anode or the cathode electrode Two projections may be formed so as to be brought into close contact with the positive electrode or the negative electrode in the second projection.

Each of the pair of belt gaskets forms a central opening for the first or second porous electrode arrangement and the second projection may surround the central opening at a predetermined distance from the center opening.

The redox flow cell of this embodiment can prevent the deformation of the gasket and thereby the deformation or the deformation of the entire stack due to the improved gasket structure, and the leakage of the electrolyte can be effectively prevented by increasing the airtightness of the stack. As a result, the durability and charge / discharge performance of the stack can be increased.

1 is a cross-sectional view of a redox flow cell according to an embodiment of the present invention.
Fig. 2 is a perspective view showing the front and back surfaces of the first flow frame of the stack shown in Fig. 1. Fig.
3 is a perspective view showing the front and back surfaces of the second flow frame of the stack shown in FIG.
4 is a perspective view of the stacked face gasket shown in Fig.
5 is a cross-sectional view of a face gasket cut along the line I-I in FIG.
6 is a schematic sectional view showing a surface gasket of an embodiment having a first projection and a surface gasket of a comparative example having no first projection.
7 is a perspective view of the stacked gasket shown in Fig.
8 is a sectional view of a gasket cut along the line II-II in FIG.
9 is a cross-sectional view of an arrow A portion of the face gasket shown in Fig.
10 is a cross-sectional view of the stack shown in FIG. 1, taken along another section.
11 is a cross-sectional view of the surface gasket cut along the line III-III in FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

1 is a cross-sectional view of a redox flow cell according to an embodiment of the present invention. The redox flow cell according to this embodiment may be a vanadium redox flow battery using vanadium ions, but is not limited thereto.

Referring to FIG. 1, the redox flow cell 100 of the present embodiment includes a stack in which a plurality of battery cells 10 are stacked. Each of the battery cells 10 includes a membrane 20 as an ion exchange membrane, first and second porous electrodes 31 and 32 positioned between the membranes 20, first and second porous electrodes 31 , 32), and includes first and second flow frames (33, 34) for fixing the first and second porous electrodes (31, 32).

Each of the battery cells 10 includes a positive electrode 35 closely attached to the outside of the first porous electrode 31 and a negative electrode 36 adhered to the outside of the second porous electrode 32. In the two adjacent battery cells 10, the anode electrode 35 and the cathode electrode 36 are integrally formed, and this is referred to as a bipolar plate 37. That is, the surface of the bipolar plate 37 facing the battery cell 10 functions as the anode electrode 35, and the surface facing the other battery cell 10 functions as the cathode electrode 36.

The membrane 20 may be formed of a fluorine-based ion exchange membrane, and the first and second porous electrodes 31 and 32 may be made of a sponge-type carbon felt having a repulsive force. The first and second flow frames 33 and 34 may be formed of a plastic material such as polyethylene or polypropylene, and the bipolar plate 37 may be formed of a graphite plate.

The first and second flow frames 33 and 34 supply the electrolytic solution to the first and second porous electrodes 31 and 32 and form a plurality of openings and a flow path for discharging the electrolytic solution used for charging and discharging. The membrane 20 can be formed in the same size as the first and second flow frames 33 and 34 and the bipolar plate 37 is larger than the first and second porous electrodes 31 and 32, And may be formed to have a size smaller than that of the second flow frames 33 and 34.

Each of the battery cells 10 also includes a pair of face gaskets 40 positioned between the first and second flow frames 33 and 34 and the membrane 20 and a pair of face gaskets 40 positioned between the first and second flow frames 33 and 34, And a pair of band gaskets 50 positioned between the bipolar plate 37 and the bipolar plate 37. The face gasket 40 and the belt gasket 50 may be formed of a fluorine-based rubber having excellent durability against an electrolyte based on an aqueous sulfuric acid solution.

A first end plate 62 provided with a positive electrode current collector plate 61 and a second end plate 64 provided with a negative electrode current collector plate 63 are located on the outermost side of the stack. The positive and negative current collecting plates 61 and 63 may be formed of a copper plate or a copper mesh and the first and second end plates 62 and 64 may be formed of a plastic material such as the flow frames 33 and 34 .

The stack of the above-described configuration can be integrally fixed by a mechanical means such as a bolt-nut after a plurality of battery cells 10 are strongly pressed by a press device (not shown). The stack is connected to a tank (not shown) storing a positive electrode electrolyte solution and a negative electrode electrolyte solution, and is supplied with a positive electrode electrolyte solution and a negative electrode electrolyte solution by a pump (not shown). As the anode and cathode electrolyte flows through the stack, discharge is caused by a charging or reducing reaction due to the oxidation reaction.

FIG. 2 is a perspective view showing a front surface and a rear surface of the first flow frame of the stack shown in FIG. 1, and FIG. 3 is a perspective view showing a front surface and a rear surface of the second flow frame of the stack shown in FIG.

Referring first to Fig. 2, the first flow frame 33 forms a central opening 331 for the arrangement of the first porous electrode 31 and four openings for electrolyte circulation. The four openings are composed of a cathode electrolyte inlet 332, a cathode electrolyte outlet 333, and two cathode electrolyte through holes 334.

The first flow frame 33 has a first flow path 335 for connecting the anode electrolyte injection port 332 and the central opening 331 and a second flow path 335 for connecting the center opening 331 and the anode electrolyte discharge port 333, A flow path 336 is formed. The positive electrode electrolyte supplied to the stack is supplied to the first porous electrode 31 through the positive electrode electrolyte injection port 332 and the first flow path 335 of each battery cell 10 and the positive electrode electrolyte used for charging or discharging And is discharged to the outside of the stack through the second flow path 336 and the anode electrolyte outlet 333.

On the rear surface of the first flow frame 33 is formed a groove gasket 50 along the edge of the central opening 331 and a recess groove 337 for seating the edge of the bipolar plate 37.

Referring to FIG. 3, the second flow frame 34 forms a central opening 341 for the second porous electrode 32 and four openings for electrolyte circulation. The four openings consist of a cathode electrolyte inlet 342, a cathode electrolyte outlet 343, and two anode electrolyte passages 344.

A third flow path 345 connecting the cathode electrolyte injection port 342 and the central opening 341 and a fourth flow path 345 connecting the central opening 341 and the cathode electrolyte discharge port 343 are formed on the back surface of the second flow frame 34. [ A flow path 346 is formed. The negative electrode electrolyte supplied to the stack is supplied to the second porous electrode 32 through the negative electrode electrolyte injection port 342 of the battery cell 10 and the third flow path 345. The negative electrode electrolyte used for charging or discharging And is discharged to the outside of the stack through the fourth flow path 346 and the cathode electrolyte outlet 343.

A concave groove 347 is formed on the front surface of the second flow frame 34 along the edge of the central opening 341 to seat the band gasket 50 and the edge of the bipolar plate 37.

In FIGS. 2 and 3, each of the first to fourth flow paths 335, 336, 345, and 346 is sealed by a cover plate (not shown) to prevent the electrolyte from leaking. The first to fourth flow paths 335, 336, 345, and 346 shown in FIGS. 2 and 3 are schematics of their shapes and are not limited to the illustrated flow paths.

FIG. 4 is a perspective view of the stacked face gasket shown in FIG. 1, and FIG. 5 is a sectional view of a face gasket cut along the line I-I of FIG.

4 and 5, a face gasket 40 is provided between the first flow frame 33 and the membrane 20 in each battery cell 10 and between the membrane 20 and the second flow frame 34 . The face gasket 40 is basically of an external size similar to the first and second flow frames 33 and 34 and forms a central opening 41 for the placement of the first or second porous electrode 31, .

The surface gaskets 40 are formed in a structure in which the first protrusions 42 of a continuous shape are formed on the surface facing the membrane 20, rather than being formed as a whole. Here, the continuous shape means a shape in which the intermediate portion is not broken but is annularly formed. In other words, the first protrusion 42 is formed so as to surround the center opening 41, and can be formed to have a constant width and a constant height.

Accordingly, the surface gasket 40 is brought into close contact with the membrane 20 at the portion of the first protrusion 42 in the process of pressing and stacking the stack after a plurality of battery cells 10 are laminated. Such a close contact structure prevents the pressure imbalance from leading to the deformation of the entire stack even if the problem of pressure squeezing occurs in the pressing process.

6 is a schematic sectional view showing a surface gasket of an embodiment having a first projection and a surface gasket of a comparative example having no first projection.

6 (A), in the surface gasket 40 of the present embodiment in which the first protrusions 42 are formed on one surface, even if an unbalance occurs in which the tightening pressure of the stack is shifted in a specific direction, only the first protrusions 42 The pressure imbalance does not lead to the deformation of the entire surface gasket 40 because the deformation is performed by the force.

However, referring to FIG. 6 (B), in the surface gasket 401 of the comparative example in which the first projection is not formed, the entire surface gasket 401 is deformed in a specific direction even if the tightening pressure of the stack is slightly deviated in a specific direction. In the stack, two face gaskets are positioned for each battery cell, and as the number of battery cells increases, the number of face gaskets also increases. Therefore, deformation of face gaskets leads to deformation and deformation of the entire stack.

In addition, the surface gasket 40 of the present embodiment in which the first protrusions 42 are formed has higher adhesion in the stack compared to the comparative structure without the first protrusions. That is, since the force is concentrated on the first protrusion 42 under the same pressure condition, the adhesion force of the surface gasket 40 is increased. Therefore, the redox flow cell 100 of the present embodiment can increase the airtightness of the stack, and effectively prevent leakage of the electrolyte solution.

FIG. 7 is a perspective view of the stacked gasket shown in FIG. 4, and FIG. 8 is a sectional view of the gasket cut along the line II-II of FIG.

7 and 8, the gasket 50 is provided between the first flow frame 33 and the bipolar plate 37 in the respective battery cells 10 and between the second flow frame 34 and the bipolar plate 37 . The bandgasket 50 basically has an outer size similar to the bipolar plate 37 and forms a central opening 51 for the first or second porous electrode 31, 32 arrangement.

The gasket 50 has a structure in which a second protrusion 52 having a continuous shape is formed on a surface facing the bipolar plate 37. The second protrusion 52 is formed to surround the center opening 51 at a predetermined distance from the center opening 51 and may be formed to have a constant width and a constant height.

Since the band gasket 50 is brought into intimate contact with the bipolar plate 37 at the portion of the second projection 52 instead of the entire surface thereof, even if uneven clamping pressure is applied to the stack, it does not cause deformation of the entire stack. It is possible to increase the tightness of the stack to improve the airtightness of the stack and effectively prevent leakage of the electrolyte.

9 is a cross-sectional view of an arrow A portion of the face gasket shown in Fig.

4 and 9, the face gasket 40 forms four electrolyte through holes 43 for electrolyte circulation, and at least two electrolyte through holes 43 of the four electrolyte through holes 43 Ring projections 44 can be formed. The O-ring protrusions 44 are formed so as to surround each of the two electrolyte through holes 43 one by one.

For example, the surface gasket 40 in contact with the first flow frame 33 can form the o-ring protrusion 44 around the two electrolyte through holes 43 through which the anode electrolyte passes, and the second flow The surface gasket 40 in contact with the frame 34 can form the o-ring protrusion 44 around the two electrolyte through holes 43 through which the negative electrode electrolyte passes.

However, the formation position of the o-ring projection 44 is not limited to the illustrated example, and the o-ring projection 44 may be formed around the four electrolyte passage holes 43. The O-ring protrusion 44 formed around the electrolyte passage hole 43 serves to replace the conventional O-ring gasket.

FIG. 10 is a cross-sectional view of the stack shown in FIG. 1 taken along another section, showing two openings among four openings for electrolyte circulation.

Ring projections 44 are formed by replacing the conventional o-ring gasket with the electrolyte through holes 43 (see FIG. 4) as the face gasket 40 forms the O-ring projections 44 around the two electrolyte through holes 43 ) To prevent leakage of electrolyte around it. The O-ring protrusions 44 prevent leakage of electrolyte around the electrolyte through holes 43 in each battery cell 10, and a conventional O-ring gasket 60 is formed on the outside of each battery cell 10 Thereby preventing electrolyte leakage.

The o-ring gasket 60 is disposed around each of the four openings for electrolyte circulation between the first flow frame 33 and the second flow frame 34 of two neighboring battery cells 10. The O-ring gasket 60 is also made of a fluorine-based rubber that is durable against the electrolyte. For the arrangement of the o-ring gasket 60, concave grooves may be formed on the outer sides of the first and second flow frames 33, 34 around each of the four openings.

11 is a cross-sectional view of the surface gasket cut along the line III-III in FIG.

Referring to Figures 4 and 11, the face gasket 40 forms an expansion accommodating portion 45, 46 that accommodates expansion by the clamping pressure. Since the face gasket 40 is made of a fluorine rubber material, when the tightening pressure of the stack is applied, the thickness becomes small and a sideways stretching (expansion) occurs.

The expansion receptacles 45 and 46 are voids formed in the face gaskets 40 to quickly accommodate laterally extending face gaskets 40 to prevent deformation of the face gaskets 40 due to pressure. That is, the surface gasket 40, which is a rubber material, is pressed by the pressure, and the thickness becomes smaller. However, the volume of the surface gasket 40 is expanded in any direction.

In the surface gasket without the expansion accommodating portions 45 and 46, since the pressurized material is difficult to move quickly to the side, defects such as wrinkles easily occur. However, in the face gasket 40 of the present embodiment in which the expansion accommodating portions 45 and 46 are formed, since the pressurized material is quickly moved to the expansion accommodating portions 45 and 46, defects such as wrinkles can be prevented, Ensuring airtightness and preventing electrolyte leakage.

The expansion accommodating portions 45 and 46 may be formed at a predetermined distance from the central opening 41 of the surface gasket 40 and the electrolyte passage hole 43. For example, the surface gaskets 40 in contact with the first flow frame 33 form respective first expansion accommodating portions 45 in the regions facing the first and second flow paths 335 and 336, Two second expansion accommodating portions 46 can be formed around the respective one of the electrolyte through holes 43.

In other words, ten expansion accommodating portions 45 and 46 can be formed in one face gasket 40 all. At this time, the first expansion accommodating portion 45 may be formed to have an area larger than that of the second expansion accommodating portion 46.

The surface gasket 40 in contact with the second flow frame 34 is also formed with the first expansion accommodating portion 45 in the region facing the third and fourth flow paths 345 and 346, Two second expansion accommodating portions 46 can be formed around each of the second expansion accommodating portions 43. [ The plurality of face gaskets 40 all have the same shape.

The first and second expansion accommodating portions 45 and 46 shown in Fig. 4 are only one example. The face gasket 40 of the present embodiment is not limited to the structure shown in the figures.

As described above, the redox flow cell 100 according to the present embodiment is configured such that the projections 42 and 52 are formed on the surface gasket 40 and the belt gasket 50 so that the deformation of the gaskets 40 and 50 And thus the deformation of the entire stack can be effectively prevented. Further, due to the expansion accommodating portions (45, 46) formed in the face gasket (40), defects such as wrinkles of the face gaskets (40) can be prevented.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Of course.

100: redox flow battery 10: battery cell
20: membrane 31, 32: first and second porous electrodes
33, 34: first and second flow frames 35, 36: anode electrode, cathode electrode
37: bipolar plate 40: face gasket
42: first projection 50: belt gasket
52: second projection

Claims (8)

First and second porous electrodes positioned across the membrane;
First and second flow frames positioned at the edges of each of the first and second porous electrodes and fixing the first and second porous electrodes;
An anode electrode and a cathode electrode which are in close contact with an outer side of each of the first porous electrode and the second porous electrode;
And a plurality of gaskets disposed in close contact with the first and second flow frames to prevent electrolyte leakage,
Wherein at least one gasket of the plurality of gaskets forms a continuous protrusion on one surface and forms a plurality of electrolyte through holes spaced apart from the protrusion, And the ring projections are integrally formed. The method according to claim 1,
Wherein the plurality of gaskets include a pair of face gaskets positioned between the first and second flow frames and the membrane,
Wherein the protrusion includes a first projection formed on a surface of the pair of face gaskets facing the membrane,
Wherein the first projection is in close contact with the membrane. 3. The method of claim 2,
Each of the pair of face gaskets defining a central opening for the first or second porous electrode arrangement,
Wherein the first protrusion is formed so as to surround the center opening at a predetermined distance from the center opening. The method of claim 3,
Wherein each of the pair of face gaskets forms the plurality of electrolyte through holes to circulate the electrolyte,
Wherein the o-ring projection is formed in each of the pair of face gaskets. 5. The method of claim 4,
Wherein each of said pair of face gaskets is made of fluorocarbon rubber and forms at least one expansion accommodating portion that accommodates sideways volumetric expansion by the tightening pressure. 6. The method of claim 5,
Wherein the first flow frame and the second flow frame form a plurality of flow paths for supplying and discharging the electrolyte,
Wherein each of the pair of face gaskets forms a first expansion accommodation portion in an area facing the plurality of flow paths and forms a second expansion accommodation portion around each of the electrolyte solution holes. 7. The method according to any one of claims 1 to 6,
Wherein the plurality of gaskets include a pair of band gaskets positioned between the first flow frame and the anode electrode and between the second flow frame and the cathode electrode,
Wherein the protrusion includes a second protrusion formed on a surface of the pair of band gaskets facing the anode or the cathode,
And the second projection is in close contact with the positive electrode or the negative electrode. 8. The method of claim 7,
Each of said pair of band gaskets forming a central opening for said first or second porous electrode arrangement,
And the second protrusion is formed so as to surround the center opening at a predetermined distance from the center opening.

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