KR101631909B1 - Composite material bipolar plate for redox flow battery - Google Patents

Abstract

Disclosed is a composite material separator for a redox flow cell, wherein the channel is formed by a concavo-convex structure and edges are formed flat to improve airtightness. The present invention includes a channel forming portion and a flat edge portion. The channel forming portion is in close contact with one surface of the electrode, and has irregularities for forming a plurality of channels on both surfaces thereof, and is disposed at a constant distance from the edge. The flat edge portion is formed flat from the channel forming portion to the edge. According to the present invention, the channel forming the electrolyte passage is formed in a concave-convex structure to increase the coupling force with the electrodes, and the flat edge portion from the channel forming portion to the edge is formed to improve the airtightness with the frame have.

Description

Technical Field [0001] The present invention relates to a composite material separator for a redox flow battery,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a redox flow cell, and more particularly, to a redox flow cell having a channel formed by a concavo-convex structure and having a flat edge to improve airtightness.

Renewable energy such as solar energy or wind energy is attracting attention in recent years as a method for suppressing the emission of greenhouse gases, which is a major cause of global warming. The renewable energy can not be continuously supplied because the output fluctuation is severe, and a time difference occurs between the point of time of energy production and the point of time of demand. Therefore, an energy storage system that stores energy when the output of the regenerative energy is high and uses the stored energy when the output is low is becoming important.

Among various energy storage systems, research and development of redox flow cells are being actively carried out as secondary batteries which are effective for storing renewable energy. A redox flow cell is an electrochemical storage device in which the active energy of an electrolyte is oxidized and reduced to charge and discharge the chemical energy of the electrolyte directly.

Such redox flow cells are disclosed in many patents such as U.S. Patent No. 8,288,030, U.S. Patent No. 8,221,911, U.S. Patent No. 7,537,859. 1, the redox flow battery 10 includes a stack 30 in which a plurality of unit cells (unit cells) 20 are stacked in series and a stack 30 in which oxidation states are different from each other And pumps 42 and 52 for circulating the active material during charging and discharging. The electrolyte of the anode and the cathode uses an acidic aqueous solution in which an active material such as vanadium (V), iron (Fe), chromium (Cr) and the like and a transition metal such as tin (Stannum, Sn) are dissolved in a strong acid aqueous solution. The stack 30 is composed of unit cells 20 and two end plates 60 and 62. The unit cells 20 and the end plates 60 and 62 are fastened by a plurality of tie rods 64.

2, the unit cells 20 are basically composed of a membrane (membrane) 22, a pair of electrodes (electrodes) 24 disposed on both sides of the membrane, and electrodes 24 And a pair of bipolar plates 26 disposed therein. The separator plate is an electrically conductive plate which may also be referred to as a bipolar plate or a flow field plate. An anode side channel is formed on one side of the separator and a cathode side channel is formed on the other side. The separator has low electrical resistance, high chemical resistance and mechanical properties, and low gas permeability to prevent leakage of hydrogen and oxygen. Also, the electrical contact resistance between two adjacent separator plates should be low. The material of the separator plate is made of graphite or stainless steel, or a polymer matrix composite in which carbon particles and graphite particles are added to a polymer matrix is used.

In the conventional composite separator for redox flow battery as described above, it is easy to assemble with the frame and the electrode, and the airtightness with the electrode should be excellent, but a separator satisfying such a separator has not been developed.

Disclosure of the Invention The present invention is intended to solve various problems of the conventional composite separator for redox flow cells. SUMMARY OF THE INVENTION An object of the present invention is to provide a composite separator for a redox flow cell in which the channel is formed in a concavo-convex structure.

Another object of the present invention is to provide a composite material separator for a redox flow cell, wherein a flat edge portion is formed from the channel forming portion formed by the unevenness to the edge to improve airtightness with the frame.

According to an aspect of the present invention, there is provided a composite material separator for a redox flow cell. The composite separator for a redox flow battery according to the present invention is a composite separator for a redox flow cell, which is in close contact with one surface of an electrode, has irregularities for forming a plurality of channels on both surfaces thereof, A portion; And a flat edge portion formed flat from the channel forming portion to the edge.

The irregularities include a plurality of ridges and a plurality of valleys alternately arranged, and the surface portion of the electrode contacting the plurality of valleys has a surface area smaller than the surface portion of the electrode contacting the plurality of ridges The compression deformation amount is small, and the electrode is made of a carbon fiber composite material.

In the composite separator for a redox flow-type battery according to the present invention, the channel forming the passage of the electrolyte is formed in a concave-convex structure to increase the coupling force with the electrodes, and a flat edge portion is formed from the channel- It is possible to improve the airtightness.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a schematic view of a general redox flow cell. FIG.
FIG. 2 is a cross-sectional view showing the configuration of the unit cell in FIG.
3 is a cross-sectional view schematically showing a stack to which a composite material separator for redox flow cells according to the present invention is applied.
4 is a perspective view illustrating a composite material separator for a redox-flow battery according to the present invention.
5 is a cross-sectional view partially showing a composite material separator for a redox flow cell according to the present invention.

Other objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments with reference to the accompanying drawings.

Hereinafter, preferred embodiments of a composite material separator for a redox flow battery according to the present invention will be described in detail with reference to the accompanying drawings.

3, a stack 100 of redox flow cells according to the present invention includes a plurality of unit cells 110 and two end plates 120 and 122. Each of the unit cells 110 includes a membrane 112, a pair of electrodes 114 disposed on both sides of the membrane 112, a pair of frames 116 in which the electrodes 114 are accommodated, . The electrodes 114 are mounted in the inner space 118 of the frames 116. The edge of the membrane 112 is interposed between the adjacent two frames 116 so as to maintain airtightness. The electrodes 114 may be composed of a carbon fiber composite material such as carbon fiber felt, unidirectional carbon fiber composite material sheet.

3 to 5, each of the unit cells 110 includes a pair of composite material separation plates 130 disposed on both sides of the electrodes 114. The composite separator 130 of the redox flow cell according to the present invention has a plurality of channels 132 formed on both sides thereof, that is, corrugations 134 or corrugations are formed so as to form an anode side channel and a cathode side channel. And a channel forming portion 136 which is formed on the substrate. The ridges 134 are composed of a plurality of ridges 134a arranged alternately and a plurality of bottoms 134b. 3 and 5, the concavities and convexities 134 may be formed in various shapes such as rhombic, triangular, semicircular, and the like.

The channel forming portions 136 are formed apart from the edges of the composite material separating plate 130 at regular intervals. The composite separator plate 130 has a flat edge portion 138 that is formed flat from the channel forming portion 136 toward the edge. The flat edge portion 138 is in close contact with both sides of the frame 116 or one surface of the end plates 120 and 122 to maintain airtightness.

The composite material separation plate 130 can be manufactured by molding a carbon fiber composite material by a hot press method. The carbon fiber composite material can be produced by impregnating a carbon fiber with a polymer matrix. The polymer base can be composed of a phenolic resin, an epoxy resin, a polyester resin, and the like. Preferably, the polymer matrix is comprised of a phenolic resin. Preferably, the composite separator plate 130 is composed of a carbon fiber reinforced phenolic resin matrix composite material in which carbon fibers are fixed by a phenolic resin. With the composite separator 130, the number of unit cells is increased by increasing the weight of the separator 130, thereby increasing the reaction area, thereby improving the power density. In addition, the contact resistance of the separator 130 is reduced to reduce the current loss in the stack 100 to improve the efficiency, and the bending strength, compressive strength, and corrosion resistance due to the fastening load are excellent, have.

When the end plates 120 and 122 are fastened by the tie rods in the stack 100 of redox flow cells according to the present invention, the membrane 112, the electrodes 114, the composite separator plate 130, The end plates 120 and 122 are brought into close contact with each other. The surfaces of the electrodes 114 in contact with the ridges 134a are compressively deformed. The surface of the electrodes 114 in contact with the bottoms 134b is less compressive than the surface of the electrodes 114 in contact with the ridges 134a. The surface portion of the electrodes 114 in contact with the bottoms 134b functions as a passage through which the electrolyte flows, that is, the channel 132 and the surface portion of the electrodes 114 in contact with the ridges 134a, It acts like a tube wall that blocks the flow of electrolyte. The flat edge portion 138 is tightly adhered to both sides of the frame 116 or one side of the end plates 120, 122.

The ridges 134a penetrate the surface of the electrodes 114 and the surface of the electrodes 114 in contact with the bottoms 134b enters into the channels 132, And the composite separating plates 130 are increased. Accordingly, when the redox flow cell is operated, the electrodes 114 of the composite material having low rigidity are effectively prevented from being deformed due to the flow of electrolyte and gravity.

On the other hand, when the ridges 134a of the two composite separator plates 130 are arranged so as to be in contact with each other, a passage closed by the channels 132 of the two composite separator plates 130 is formed. The passageway can be used as a coolant passageway or it can be filled with insulation in the passageway. The contact ridges 134a of the two composite separator plates 130 are brought into contact with each other, so that the electrical contact resistance between the two composite separator plates 130 can be reduced.
As shown in Fig. 3, the composite separator for redox flow battery of the present invention is in close contact with a pair of composite electrodes disposed on both sides of the membrane, and has a plurality of ridges And a channel forming part having a plurality of valley bottoms, each of which is formed by the ridges and valleys forming gentle curvature of the bottom of the ridges and valleys.
In the composite material separator, the portion where the ridge and the bottom of the bottom contact with the surface of the composite electrode is locally compressed to compressively deform the composite electrode, and the portion where the ridge and the bottom of the composite are not in contact with the surface of the composite electrode, Compression deformation is less than the area where the floor touches the surface of the composite electrode, creating a space between the surface of the composite electrode and the ridge and a space between the surface of the composite electrode and the bottom of the channel.

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, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100: stack 110: unit cell
112: membrane 114: electrode
116: frame 120, 122: end plate
130: composite material separation plate 132: channel
134: Unevenness 134a: Ridgeline
134b: valley bottom 136: channel forming part
138: flat edge portion

Claims (2)

A plurality of ridges and a plurality of ridges alternately arranged on both surfaces of the membrane, the ridges and the bottoms of the ridges being in gentle shape And a channel forming portion formed by the irregularities forming the bend,
A portion of the ridge and bottom of the composite material contacting the surface of the composite electrode is locally compressed so that the composite electrode is compressively deformed and a portion where the ridge and the bottom of the composite are not in contact with the surface of the composite electrode, And the space between the surface of the composite electrode and the bottom of the valley becomes smaller than that of the portion of the bottom of the composite electrode which is in contact with the surface of the composite electrode, And the channel forming portion is formed. The method according to claim 1,
Wherein the irregularities include a plurality of alternatingly arranged ridges and a plurality of valleys and a surface portion of the electrode in contact with the plurality of valleys comprises a plurality of ridges for contacting the plurality of ridges Wherein the electrode is made of a carbon fiber composite material. 2. The separator according to claim 1, wherein the electrode is made of a carbon fiber composite material.

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