KR20140148147A - Secondary Battery - Google Patents

Abstract

The present invention relates to an ion exchange membrane and a secondary battery comprising an electrode bonded to the same. The present invention aims to provide the secondary battery that can prevent the ion exchange membrane from being swollen. According to an embodiment of the present invention, the ion exchange membrane can be prevented from being swollen. Therefore, a cross over phenomenon between a positive electrode and a negative electrode resulted from the swollen ion exchange membrane can be prevented; contact resistance between the ion exchange membrane and an electrode is reduced; and consequently, efficiency of the battery can be increased.

Description

Secondary Battery

The present invention relates to a secondary battery, and more particularly, to a redox flow energy storage device.

Generally, the power supply system is mainly composed of thermal power generation. However, thermal power generation is causing environmental pollution problem due to a large amount of carbon dioxide generated by combustion of fossil fuel. In order to solve such environmental pollution problem, There is an increasing interest in.

The redox flow energy storage device is closely related to the utilization of environmentally friendly energy, and the redox flow energy storage device can easily change the output and energy density by varying the tank capacity and the cell stack number And it can be used semi-permanently. Therefore, it is attracting attention for large-capacity power storage.

Such a redox flow energy storage device is a battery that charges and discharges by using a redox reaction of a metal ion of which the valence is changed. Hereinafter, a conventional redox flow energy storage device will be described with reference to the drawings.

1 is a schematic cross-sectional view of a conventional redox flow energy storage device.

1, the conventional redox flow storage device includes an ion exchange membrane 10 and an anode 20 and a cathode 30 formed with the ion exchange membrane 10 interposed therebetween.

The redox reaction of metal ions occurs between the anode 20 and the cathode 30 through the ion exchange membrane 10, and electricity is generated by the oxidation-reduction reaction.

The anode 20 is disposed on one side of the ion exchange membrane 10 and the cathode 30 is disposed on the other side of the ion exchange membrane 10. In particular, the anode 20 and the cathode 30 are disposed on one side and the other side of the ion exchange membrane 10, respectively, and are not bonded to the ion exchange membrane 10.

Thus, in the conventional redox flow storage device, the anode 20 and the cathode 30 are not bonded to the ion exchange membrane 10, which has the following drawbacks.

Ions are moved between the anode 20 and the cathode 30 through the ion exchange membrane 10. When the secondary battery is used for a long time, the passage through which the ions move is expanded, (Swelling) phenomenon occurs.

When a phenomenon of component development occurs in the ion exchange membrane 10, a cross over phenomenon occurs in which the electrolyte moves between the anode 20 and the cathode 30, causing a voltage drop of the battery.

When the phenomenon of component development occurs in the ion exchange membrane 10, the contact resistance between the ion exchange membrane 10 and the anode 20 or between the ion exchange membrane 10 and the anode 30 is increased, There is a problem in that it is lowered.

SUMMARY OF THE INVENTION The present invention has been devised to overcome the above-described problems of the prior art, and it is an object of the present invention to provide a secondary battery capable of preventing a swelling phenomenon occurring in an ion exchange membrane.

In order to achieve the above object, the present invention provides an ion exchange membrane comprising: an ion exchange membrane; And an electrode bonded to the ion exchange membrane.

According to the present invention as described above, the following effects can be obtained.

According to one embodiment of the present invention, since the electrode is bonded to the ion exchange membrane, the electrode functions as a support for maintaining the shape of the ion exchange membrane, and swelling of the ion exchange membrane can be prevented. Therefore, the cross-over phenomenon between the anode and the cathode caused by the component development of the ion exchange membrane is prevented, and the contact resistance between the ion exchange membrane and the electrode is reduced, and as a result, the cell efficiency can be improved.

In addition, according to an embodiment of the present invention, since the unit cells are formed with the electrodes bonded to the ion exchange membrane, the assembling process for manufacturing the secondary battery is advantageous.

1 is a schematic cross-sectional view of a conventional redox flow energy storage device.
2 is a schematic cross-sectional view of a redox flow energy storage device according to an embodiment of the present invention.
3 is a schematic cross-sectional view of a unit cell constituting a redox flow energy storage device according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 2 is a schematic cross-sectional view of a redox flow energy storage device according to an embodiment of the present invention, and FIG. 3 is a schematic cross-sectional view of a unit cell forming a redox flow energy storage device according to an embodiment of the present invention .

2, the redox flow storage device according to one embodiment of the present invention includes an ion exchange membrane 100, electrodes 200a and 200b, bipolar plates 300a and 300b, current collectors 400a and 400b , Tanks 500a and 500b, and pipes 610a, 610b, 620a, and 620b.

The ion exchange membrane 100 serves as a passage through which the ions move between the electrodes 200a and 200b during charging and discharging of the secondary battery. It is preferable that the ion exchange membrane 100 has high ion selective permeability, high conductivity, high chemical resistance and durability. As the ion exchange membrane 100, a cation exchange membrane or an anion exchange membrane can be used. Specifically, Nafion can be used, but it is not limited thereto.

The electrodes 200a and 200b include an anode 200a located on one side of the ion exchange membrane 100 and a cathode 200b located on the other side of the ion exchange membrane 100. [

The combination of the ion exchange membrane 100, the anode 200a and the cathode 200b constitutes a unit cell, and a redox reaction occurs in the unit cell. That is, the oxidation-reduction reaction of metal ions occurs between the anode 200a and the cathode 200b through the ion exchange membrane 100, and electricity is generated by the oxidation-reduction reaction. Further, the generated electricity is drawn out via the bipolar plates 300a and 300b and the current collectors 400a and 400b.

In particular, an embodiment of the present invention can be made of a vanadium redox flow energy storage device using vanadium ions. The vanadium redox flow energy storage device is a secondary battery that can contribute to power leveling with large capacity power storage. However, the present invention is not necessarily limited thereto, and the present invention can be applied to a redox flow energy storage device using various electrolytes other than vanadium.

The anode 200a and the cathode 200b include a carbon felt. The carbon felt may be made of carbon, graphite, or a mixture of carbon and graphite depending on the degree of carbonization. The surface of the carbon felt can be subjected to surface treatment. That is, surface treatment such as acid treatment or electrochemical treatment may be performed on the carbon felt to improve the wettability of the carbon felt with respect to the aqueous electrolyte.

At least one of the anode 200a and the cathode 200b is bonded to the ion exchange membrane 100. That is, only the anode 200a can be bonded to the ion exchange membrane 100 at one side of the ion exchange membrane 100, and only the cathode 200b can be bonded to the ion exchange membrane 100 at the other side of the ion exchange membrane 100, And both the anode 200a and the cathode 200b may be bonded to the ion exchange membrane 100. [

As described above, according to the present invention, since at least one of the anode 200a and the cathode 200b is bonded to the ion exchange membrane 100, in other words, the anode 200a and the cathode 200b, Since at least one of the ion exchange membranes 100 is fixed to the ion exchange membrane 100 without being separated from the ion exchange membrane 100, when ions move through the ion exchange membrane 100, Can be prevented.

That is, since the anode 200a and / or the cathode 200b are bonded to the ion exchange membrane 100, the anode 200a and / or the cathode 200b can be maintained in the shape of the ion exchange membrane 100 So that the ion exchange membrane 100 does not swell up. Therefore, the problems of cross over and contact resistance increase due to the phenomenon of the conventional ion exchange membrane 10 parts phenomenon can be solved.

3, in the bonding of the anode 200a and the cathode 200b to the ion exchange membrane 100, the anode 200a and the cathode 200b are bonded to each other, 200b may penetrate the surface of the ion exchange membrane 100 and penetrate the surface thereof.

When the carbon felt penetrates the surface of the ion exchange membrane 100 and penetrates into the interior thereof, the bonding force between the anode 200a and the ion exchange membrane 100 and the bonding force between the cathode 200b and the ion exchange membrane 100, The bonding force between the substrate 100 and the substrate 100 can be enhanced. When the carbon felt penetrates the surface of the ion exchange membrane 100 and penetrates into the interior of the ion exchange membrane 100, the movement of ions between the anode 200a and the cathode 200b through the ion exchange membrane 100 It can be smoothed more smoothly.

In FIG. 3, all of the carbon felt constituting the anode 200a and the cathode 200b are configured to penetrate the surface of the ion exchange membrane 100 and penetrate into the interior thereof. However, And only one of the carbon felt constituting the anode 200a and the cathode 200b penetrates the surface of the ion exchange membrane 100 and penetrates into the interior thereof.

The unit cell in which the anode 200a and / or the cathode 200b are bonded to the ion exchange membrane 100 may be formed by heating the ion exchange membrane 100 to a temperature not lower than the glass transition temperature, ) And pressing the carbon felt to one side and / or the other side of the carbon felt.

Referring again to FIG. 2, the bipolar plates 300a and 300b serve as conductors for transferring electric charges. The bipolar plates 300a and 300b are connected to current collectors 400a and 400b as shown in FIG. 2, and charge generated in the electrodes 200a and 200b is extracted through the current collectors 400a and 400b . Also, although not shown, when a plurality of unit cells are stacked, the bipolar plates 300a and 300b may be positioned between the anode 200a of one unit cell and the cathode 200b of another unit cell, The bipolar plate 300a 300b transmits the charge generated through the anode 200a of one unit cell and the cathode 200b of the other unit cell to the other electrode do.

The bipolar plates 300a and 300b may be made of a material selected from a plastic composite containing graphite, graphite or carbon, and gold / platinum coated metal.

The current collectors 400a and 400b are preferably electrically connected to the bipolar plates 300a and 300b, respectively, in the outermost bipolar plates 300a and 300b, respectively, when a plurality of unit cells are stacked. However, when a plurality of unit cells are stacked, a current collector may be additionally connected to a bipolar plate located between the anode of one unit cell and the cathode of another unit cell, which are not the outermost unit cells.

As the current collectors 400a and 400b, any material having good conductivity may be used, but copper may be preferably used.

The tanks 500a and 500b include a positive electrode electrolyte tank 500a connected to the positive electrode 200a and a negative electrode electrolyte tank 500b connected to the negative electrode 200b.

The positive electrode electrolyte tank 500a stores a positive electrode electrolyte, so that the positive electrode electrolyte flows between the positive electrode electrolyte tank 500a and the positive electrode 200a. Also, the negative electrode electrolyte tank 500b stores the negative electrode electrolyte, and the negative electrode electrolyte flows between the negative electrode electrolyte tank 500b and the negative electrode 200b.

The positive electrode electrolyte may include a vanadium tetravalent ion or a vanadium pentacene ion, and the negative electrode electrolyte may include a vanadium divalent ion or a vanadium trivalent ion. Thus, one embodiment of the present invention can be made of a vanadium redox flow energy storage device using vanadium ions. However, the present invention is not necessarily limited thereto, and the present invention can be applied to a redox flow energy storage device using various electrolytes other than vanadium.

The pipes 610a, 610b, 620a, and 620b include a cathode electrolyte inlet pipe 610a, a cathode electrolyte inlet pipe 610b, a cathode electrolyte outlet pipe 620a, and a cathode electrolyte outlet pipe 620b.

The positive electrode electrolyte inflow pipe 610a connects the positive electrode electrolyte tank 500a and the positive electrode 200a to transfer the positive electrode electrolyte stored in the positive electrode electrolyte tank 500a to the positive electrode 200a. The negative electrode electrolyte inflow pipe 610b connects the negative electrode electrolyte tank 500b and the negative electrode 200b to transfer the negative electrode electrolyte stored in the negative electrode electrolyte tank 500b to the negative electrode 200b.

The positive electrode electrolyte outflow pipe 620a connects the positive electrode electrolyte tank 500a and the positive electrode 200a to transfer the positive electrode electrolyte from the positive electrode 200a to the positive electrode electrolyte tank 500a. The cathode electrolyte discharge pipe 620b connects the cathode electrolyte tank 500b and the cathode 200b to transfer the cathode electrolyte from the cathode 200b to the cathode electrolyte tank 500b.

The present invention is not limited to the structure of the redox flow energy storage device described above. The present invention is not limited to the structure of the redox flow energy storage device described above. The present invention can be applied to the case where the anode 200a and / 100). ≪ RTI ID = 0.0 > [0040] < / RTI >

100: ion exchange membrane
200a: anode 200b: cathode
300a, 300b: bipolar plate 400a, 400b: collector
500a, 500b: Tanks 610a, 610b, 620a, 620b: Piping

Claims (6)

Ion exchange membranes; And
And an electrode bonded to the ion exchange membrane. The method according to claim 1,
Wherein the electrode is a cathode located on one side of the ion exchange membrane or a cathode located on the other side of the ion exchange membrane. The method according to claim 1,
Wherein the electrode penetrates the surface of the ion exchange membrane and penetrates into the interior thereof. The method according to claim 1,
Wherein the electrode comprises carbon felt. The method according to claim 1,
And an electrolyte including vanadium ions supplied to the electrode. The method according to claim 1,
Wherein the secondary battery is a redox flow energy storage device.

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