KR20230096946A - Redox flow battery preventing electrolyte leakage and stacking method thereof - Google Patents

Abstract

The present invention relates to a redox flow battery with enhanced sealing and a laminating method thereof, which includes an end plate, a PVC head plate, a first current collector, a first positive electrode plate, a cell, a second positive electrode plate, a second current collector, and a central electrolyte distribution pipe. A stack comprising a configured stack, wherein the cell is composed of an anode flow frame, a first electrode, a separator, a cathode flow frame, and a second electrode, and the anode flow frame and the cathode flow frame include a cover plate. .

Description

Redox flow battery preventing electrolyte leakage and stacking method thereof

The present invention relates to a redox flow battery, and more particularly, to a redox flow battery preventing leakage of electrolyte and a stacking method of the redox flow battery.

Recently, as the use of energy due to depletion of fossil fuels and environmental pollution is limited, the proportion of new and renewable energies is increasing. However, since the power generated from renewable energy sources is not constant, an energy storage system (ESS; Energy Storage System) for stable power supply and a power storage device capable of high capacity and excellent operation stability are redox flow batteries (RFB, Redox Flow Battery) is being studied.

1 shows a redox flow battery. Referring to FIG. 1(a), the redox flow battery receives electricity from an external power system or a renewable power source and emits electrons into the electrolyte of the anode and cathode, and electrons are generated on the other side. It is a battery that receives and produces electricity flow. In addition, it is possible to store and charge electricity and, on the contrary, to release electrons in the electrolyte of the positive and negative electrodes of the redox flow battery to the power system, and it is possible to play a role in greatly adjusting the load at the peak load and minimum load point of the power system. It is a power storage device that can respond to stable power supply. In addition, the development of a power storage device is continuously being made because the capacity loss due to repeated charging and discharging is low, the lifespan is long, and the operating cost is low.

In general, a conventional redox flow battery constitutes a cell by stacking an electrode, a separator, a positive plate (bipolar plate, BP, Bipolar plate), a current collector, and a flow frame as shown in FIG. Electrolyte flows into the cell and works.

At this time, since the conventional redox flow batteries are stacked and then fixedly coupled through fastening means such as bolts and nuts, continuous pressure is applied to the edge portions of the cell frames, especially the manifold portion including the inlet and outlet through which the electrolyte flows. There is a problem in that overheating is applied and deformation occurs, and leakage and short circuit of the electrolyte solution occur.

Accordingly, the present invention is intended to provide a redox flow battery and a stacking method thereof in which electrolyte leakage is prevented in order to improve the above problems.

An object of the present invention is to provide a redox flow battery preventing leakage of electrolyte and a method for stacking the same.

In addition, an object of the present invention is to provide a structure for efficient sealing while maximizing the response area of the stack and minimizing the shape dimensions (height, width, thickness) of the stack.

However, these tasks are illustrative, and the scope of the present invention is not limited thereby.

According to one aspect of the present invention for achieving the above object, a stack composed of an end plate, a PVC head plate, a first current collector, a first positive electrode plate, a cell, a second positive electrode plate, a second current collector, and a central electrolyte distribution pipe is included. The cell is composed of an anode flow frame, a first electrode, a separator, a cathode flow frame, and a second electrode, and the anode flow frame and the cathode flow frame include a cover plate. A dox flow battery is provided.

According to one embodiment of the present invention, the end plate is composed of a metal head plate, the rear surface of the end plate includes a frame, and the thickness of the frame may be twice or more than the thickness of the end plate.

According to one embodiment of the present invention, the stack includes a plurality of cells and may be formed by continuously stacking the cells.

According to an embodiment of the present invention, the stack may be formed by stacking 2N (N+N) cells.

According to an embodiment of the present invention, the anode flow frame includes a first anode flow frame and a second anode flow frame, and the front portion of the first anode flow frame includes an outer sealing portion, an electrolyte flow path, and a manifold sealing portion The rear part of the first anode flow frame includes a positive plate (bipolar plate, BP) sealing part, and the front part of the second anode flow frame includes an outer sealing part, an electrolyte flow path, and a manifold sealing part, and the second The rear part of the positive flow frame may include a positive plate sealing part and an outer sealing part.

According to one embodiment of the present invention, the cathode flow frame includes a first cathode flow frame and a second cathode flow frame, and the front portion of the first cathode flow frame includes an outer sealing portion, an electrolyte flow path, and a manifold sealing portion and a separator sealing part, wherein the rear part of the first cathode flow frame includes a positive plate sealing part, a positive plate (bipolar plate, BP) sealing part, and an outer sealing part, and the front part of the second cathode flow frame includes an outer sealing part and an electrolyte flow path and a manifold sealing part and a separator sealing part, and the back side of the second cathode flow frame may include a positive plate (bipolar plate, BP) sealing part.

According to one embodiment of the present invention, the stack includes a plurality of positive electrode plates (bipolar plates, BPs), and the plurality of positive electrode plates (bipolar plates, BPs) are two more than the number of cells (2N) it could be

According to another aspect of the present invention, in the method of stacking a stack around a central electrolyte distribution pipe, a first step of laminating a PVC head plate on an end plate, and a first step of laminating a first current collector on the PVC head plate 2nd step, 3rd step of stacking a first positive electrode plate (bipolar plate, BP) on the first current collector, 4th step of stacking a cell on the first positive electrode plate (bipolar plate, BP), on the cell A fifth step of stacking a second positive electrode plate (bipolar plate, BP), a sixth step of stacking a second current collector on the second positive electrode plate (bipolar plate, BP), and a central electrolyte distribution pipe on the second current collector It provides a method of stacking a redox flow battery with enhanced sealing, which includes a seventh step of stacking.

According to one embodiment of the present invention, the fourth step of stacking the cells includes stacking the anode flow frame on the first cathode plate (bipolar plate, BP), and attaching the first electrode to the front side of the anode flow frame. Inserting step: stacking a separator on the first electrode, stacking the front side of the cathode flow frame so that the front side of the cathode flow frame abuts, and inserting a second electrode on the rear side of the cathode flow frame. it may be

According to one embodiment of the present invention, the fourth step of stacking the cells may include forming the anode flow frame and the cathode flow frame.

According to an embodiment of the present invention, the forming of the anode flow frame and the cathode flow frame may include bonding electrolyte flow paths of the anode flow frame and the cathode flow frame with a cover plate.

According to an embodiment of the present invention, the step of stacking the anode flow frames may include stacking a first anode flow frame and a step of stacking a second anode flow frame.

According to one embodiment of the present invention, the step of laminating the first anode flow frame may include inserting an outer sealing agent and a manifold sealing agent into the front portion of the first anode flow frame, and It may be to insert a positive plate (bipolar plate, BP) sealing agent into the rear part.

According to one embodiment of the present invention, the step of laminating the second anode flow frame may include inserting an outer sealing agent and a manifold sealing agent into the front portion of the second anode flow frame, and It may be to insert a positive plate (bipolar plate, BP) sealing material and an outer sealing material into the rear part.

According to an embodiment of the present invention, the stacking of the cathode flow frames may include stacking a first cathode flow frame and stacking a second cathode flow frame.

According to an embodiment of the present invention, the step of stacking the first cathode flow frame includes inserting an outer sealing agent, a manifold sealing agent, and a separator sealing agent into a front portion of the first cathode flow frame, and A positive plate (bipolar plate, BP) sealing material and an outer sealing material may be inserted into the back side of the cathode flow frame.

According to an embodiment of the present invention, the step of stacking the second cathode flow frame includes inserting an outer sealing agent, a manifold sealing agent, and a separator sealing agent into a front portion of the second cathode flow frame, and A positive plate (bipolar plate, BP) sealing material may be inserted into the back side of the negative flow frame.

According to one embodiment of the present invention, the fourth step of stacking the cells is to stack the cells continuously, and may include including a bipolar plate (BP) between the continuously stacked cells and the cells.

According to one embodiment of the present invention, if the cells formed to contact the first positive electrode plate are the first positive electrode flow frames, the cells contacting the second positive electrode plate are the second negative flow frames, and the cells formed to contact the first positive electrode plate are the first In the case of one cathode flow frame, a cell contacting the second cathode plate may be a second cathode flow frame.

According to one embodiment of the present invention, the method of stacking the stack includes continuously stacking N cells on one surface of the central electrolyte distribution pipe and sequentially stacking N cells on the other surface of the central electrolyte distribution pipe. can

According to one embodiment of the present invention, the poles of the cells stacked on one side of the central electrolyte distribution pipe and the cells stacked on the other side of the central electrolyte distribution pipe are the same, and the step of stacking the cells on the other side of the central electrolyte distribution pipe is the same. Cells may be stacked on one side of the electrolyte distribution pipe in the reverse order of stacking the cells.

According to one embodiment of the present invention, the poles of the cells stacked on one side and the cells stacked on the other side of the central electrolyte distribution pipe are different, and the step of stacking the cells on the other side of the central electrolyte distribution pipe is the center It may be to laminate in the same order as the step of stacking the cells on one side of the electrolyte distribution pipe.

The present invention has the effect of providing a redox flow battery and a stacking method thereof preventing electrolyte leakage.

In addition, there is an effect of presenting a structure for efficient sealing while maximizing the response area of the stack and minimizing the shape dimensions (height, width, thickness) of the stack.

A further scope of the applicability of the present invention will become apparent from the detailed description that follows. However, since various changes and modifications within the spirit and scope of the present invention can be clearly understood by those skilled in the art, it should be understood that the detailed description and specific examples such as preferred embodiments of the present invention are given by way of example only.

1 is a schematic diagram showing the structure of a redox flow battery and the configuration of a stack.
2 is a schematic diagram illustrating a stack structure of a stack according to an exemplary embodiment.
3 is a front view of an end plate according to one embodiment.
4 is a rear view of an end plate according to an exemplary embodiment.
5 is a front view of a PVC head plate according to one embodiment.
6 is a rear view of a PVC head plate according to an embodiment.
7 is a front view of a first anode flow frame according to an exemplary embodiment.
8 is a rear view of the first anode flow frame according to an exemplary embodiment.
9 is a schematic diagram of a flow frame cover plate according to one embodiment.
10 is a front view of a first cathode flow frame according to an exemplary embodiment.
11 is a rear view of a first cathode flow frame according to an exemplary embodiment.
12 is a front view of a second anode flow frame according to an exemplary embodiment.
13 is a rear view of the second anode flow frame according to an exemplary embodiment.
14 is a front view of a second cathode flow frame according to an exemplary embodiment.
15 is a rear view of the second cathode flow frame according to an exemplary embodiment.
16 is a schematic diagram illustrating a laminated structure and a sealing structure inside a stack according to an exemplary embodiment.
17 is a schematic diagram showing a mirror image structure of a flow frame according to an embodiment.
18 is a schematic diagram illustrating arrangement of electrodes having a mirror image structure according to an exemplary embodiment.
19 is a schematic diagram illustrating arrangement of electrodes having a non-mirror structure according to an exemplary embodiment.
20 is a schematic diagram showing a stack of a redox flow battery in which 80 cells are stacked according to an embodiment.
21 is a graph showing cycle-by-cycle efficiency of a redox flow battery stack according to an embodiment.
22 is a graph showing cycle-by-cycle charge/discharge capacities and utilization rates of a ㄸ·Rn redox flow battery stack according to an embodiment.

Hereinafter, the present invention will be described in detail with reference to embodiments and drawings of the present invention. These examples are only illustratively indicated to explain the present invention in more detail, and it is obvious to those skilled in the art that the scope of the present invention is not limited by these examples. something to do.

In addition, unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by a person skilled in the art to which the present invention belongs, and in case of conflict, this specification including definitions of will take precedence.

In order to clearly explain the proposed invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification. And when it is said that a certain component "includes", it means that it may further include other components, not excluding other components unless otherwise stated. In addition, a “unit” described in the specification means one unit or block that performs a specific function.

In each step, the identification code (first, second, etc.) is used for convenience of description, and the identification code does not describe the order of each step, and each step does not clearly describe a specific order in context. It may be performed differently from the order specified above.

That is, each step may be performed in the same order as specified, may be performed substantially simultaneously, or may be performed in the reverse order.

In a redox flow battery, liquid electrolytes of a positive electrode and a negative electrode must flow into the battery in a separated state. However, as shown in FIG. 1, the electrolyte of the redox flow battery is supplied from an external tank to the inside of the battery in a pressurized state by a pump, and thus electrolyte mixing inside the battery and leakage of the electrolyte to the outside may occur. , the efficiency and usable capacity of the redox flow battery are reduced by the above phenomenon. Therefore, the sealing structure for preventing the mixing of the electrolyte and the leakage of the electrolyte to the outside is an essential element for the redox flow battery.

Accordingly, an object of the present invention is to provide a vanadium redox flow battery and a method for stacking the same to prevent leakage of the electrolyte.

2 is a schematic diagram illustrating a stack structure of a stack 1000 according to an exemplary embodiment. Referring to FIG. 2, the vanadium redox flow battery stack includes an end plate 100, a PVC head plate 200, a first current collector 300, a first positive electrode plate (B1, bipolar plate, BP), and cells 500 and 600. , 700), a second positive electrode plate (B2), a second current collector 800, and a central electrolyte distribution pipe 900.

3 is a front view of end plates 100 and 100' according to an embodiment, and FIG. 4 is a rear view of end plates 100 and 100' according to an embodiment.

Referring to FIGS. 3 and 4 , the end plates 100 and 100′ are thin metal mirrors and are disposed at the outermost part of the stack 1000. At this time, it is preferable to use aluminum as the metal mirror plate.

Meanwhile, when the lamination of the stack 1000 is completed and bolts and nuts are fastened to the edges, a convex phenomenon may occur in the central portion. Accordingly, in order to prevent the convex phenomenon and support the end plates 100 and 100' flat, frames 110 and 120 are included on the rear surface of the end plate 100, and the thickness of the frames 110 and 120 is It is preferably more than twice the thickness of the end plates 100 and 100'.

Meanwhile, the frame is not limited as long as it is disposed on the rear surface of the end plate 100 as long as it prevents bending of the rear surface. For example, the frame may be formed in a bar shape and disposed vertically or horizontally on the rear surface of the end plate 100, or simultaneously disposed horizontally and vertically. In addition, it may be arranged to cover the entire area of the rear surface.

5 is a front view of PVC heads 200 and 200′ according to an embodiment, and FIG. 6 is a rear view of the PVC heads 200 and 200′ according to an embodiment.

5 and 6, the PVC head plates 200 and 200' are disposed between the end plates 100 and 100' and the first current collector 300 to determine the position of the first current collector 300. It is characterized by fixing and insulating the end plate 100 and the first current collector 300.

The positive plates (B1, B2, B3, B4, bipolar plates, BP) serve to conduct electricity, and include a first positive plate (B1) and a second positive plate (B2).

The cells 500, 600, and 700 include anode flow frames 510, 610, and 710, first electrodes 520, 620, and 720, separators 530, 630, and 730, and second electrodes 540, 640, and 740. ) and a cathode flow frame (550, 650, 750).

In detail, the stack 1000 includes a plurality of cells 400, and N cells are disposed on one side of the central electrolyte distribution pipe 900 based on the central electrolyte distribution pipe 900, It is characterized in that N cells are arranged on the other surface of the central electrolyte distribution pipe 900 to include 2N (N+N) cells.

In addition, the plurality of cells 400 further include the positive electrode plates B1, B2, B3, and B4 to conduct electricity between the cells 500, 600, and 700 and the cells 500, 600, and 700. characterized by

Specifically, in order to conduct electricity between the first electrodes 520, 620, 720 and the second electrodes 540, 640, 740 constituting the cells 500, 600, and 700, the third positive electrode plate B3 ) and a fourth positive electrode plate (B4). At this time, it is preferable that the positive electrode plates B1 , B2 , B3 , and B4 include two more than the number of cells 400 . That is, it is preferable to include 2N+2 of the positive electrode plates B1, B2, B3, and B4.

7 is a front view of the first anode flow frame 510 according to an embodiment, and FIG. 8 is a rear view of the first anode flow frame 510′ according to an embodiment. 9 is a schematic diagram of a flow frame cover plate according to one embodiment.

7 and 8, the front portion of the first anode flow frame 510 includes an outer sealing portion 512, an electrolyte flow path 511, and a manifold sealing portion 513, and the first anode flow The rear portion of the frame includes a positive plate sealing portion 516 .

The electrolyte flow path 511 is disposed above and below the first anode flow frame 510, and the flow frame cover plates C1 and C2 are respectively installed on the upper and lower portions of the electrolyte flow path so that the electrolyte does not leak out and flow. It is characterized in that it is inserted into and attached by bonding with an adhesive.

The manifold sealing portion 513 seals the manifold sealing portion 513 using a sealing material so that the electrolyte does not leak while the electrolyte flows between the stacked cells 500, 600, and 700 through the manifold. characterized by

The outer sealing portion 512 is disposed on the outermost side of the first anode flow frame 510, and surrounds the electrolyte passage 511 and the manifold sealing portion 513 of the first anode flow frame. characterized by the formation of

At this time, the outer sealing portion 512 is to prevent electrolyte from leaking out of the gap between the anode and the cathode and flowing out of the stack, and the outer sealing portion 512 is sealed using an outer sealing agent.

The positive electrode plate sealing part 516 is disposed in the central portion of the rear surface of the first positive electrode flow frame 510', and the electrolyte flows through the gap between the first positive electrode flow frame 510' and the first positive electrode plate B1. It is characterized in that the positive electrode plate sealing portion 516 is sealed using a sealing material to prevent leakage.

10 is a front view of the first cathode flow frame 550 according to an embodiment, and FIG. 11 is a rear view of the first cathode flow frame 550′ according to an embodiment.

10 and 11, the front portion 550 of the first cathode flow frame includes an outer sealing portion 552, an electrolyte flow path 551, a manifold sealing portion 553, and a separator sealing portion 554. And, the rear part 550' of the first cathode flow frame is characterized in that it includes a positive plate sealing part 556 and an outer sealing part 557.

The separator sealing part 554 is disposed to surround the empty space of the front side of the first cathode flow frame 550, and the separation membrane and electrode, the first anode flow frame 510 and the first cathode flow frame 550 It is characterized in that the separator sealing portion 554 is sealed using a sealing material so that the electrolyte does not leak through.

12 is a front view of the second anode flow frame 610 according to an embodiment, and FIG. 13 is a rear view of the second anode flow frame 610′ according to an embodiment.

12 and 13, the front portion of the second anode flow frame 610 includes an outer sealing portion 612, an electrolyte flow path 611, and a manifold sealing portion 613, and the second anode flow The rear portion of the frame 610' includes an outer sealing portion 612', a positive plate sealing portion 616, and a manifold sealing portion 613'.

In detail, the second anode flow frames 610 and 610′ are disposed in the center of the plurality of cells 400, and should prevent leakage of electrolyte between the cells. Therefore, it is preferable to include the manifold sealing part 613' not only on the front part 610 of the second anode flow frame but also on the rear part 610' of the second anode flow frame.

At this time, the rear part 510 ′ of the first positive electrode flow frame is in contact with the first positive electrode plate B1 and there is no space through which the electrolyte flows. Therefore, there is no manifold, and therefore, the manifold sealing part also does not exist.

14 is a front view of the second cathode flow frame 750 according to an embodiment, and FIG. 15 is a rear view of the second cathode flow frame 750′ according to an embodiment.

14 and 15, the front portion of the second cathode flow frame 750 includes an outer sealing portion 752, an electrolyte flow path 751, a manifold sealing portion 753, and a separator sealing portion 754 And, the rear side of the second cathode flow frame 750' is characterized in that it includes a positive electrode plate sealing portion 756.

Meanwhile, the first positive electrode flow frame 510 is positioned to contact the first positive electrode plate B1, and the second negative electrode flow frame 750 is positioned to contact the second positive electrode plate B2. It is preferable that the thickness is thick compared to the first cathode flow frame 550 and the second anode flow frame 610 located therein.

In the case of the first cathode flow frame 550 and the second cathode flow frame 610 located in the center, the thickness of the third positive electrode plate B3 or the fourth positive electrode plate B4 located in the center is halved. This is because the first positive electrode flow frame 510 and the second negative electrode flow frame 750 further include a thickness equal to the thickness of the first positive electrode plate B1 or the second positive electrode plate B2.

16 is a schematic diagram illustrating a laminated structure and a sealing structure inside a stack according to an exemplary embodiment.

Referring to FIG. 16, the outer sealing part is formed on the front and rear parts of the anode flow frame and the front and rear parts of the cathode flow frame, and is preferably arranged in a zigzag pattern so that the sealant does not rub against each other.

For example, it is preferable that the outer sealing portion included in the front portion of the anode flow frame is located outside the outer sealing portion included in the front portion of the cathode flow frame. In other words, it is preferable that the outer sealing part included in the front part of the cathode flow frame is disposed inside the outer sealing part included in the front part of the cathode flow frame.

In addition, it is preferable that the outer sealing part included in the rear surface of the cathode flow frame is located outside the outer sealing part included in the rear surface of the cathode flow frame. In other words, it is preferable that the outer sealing part included in the rear surface of the anode flow frame is disposed inside the outer sealing part included in the rear surface of the cathode flow frame.

That is, the effect of sealing can be improved by arranging the outer sealing portion in a zigzag pattern.

Furthermore, the sealing agent included in each of the sealing parts is characterized in that it has corrosion resistance and water resistance. For example, it is preferable to use a sealing agent having durability equal to or higher than that of Aquaflex sealing material, acetic silicone material, EPDM (ethylene propylene diene) gasket, and plastic sealant (polyester resin). .

In addition, the sealing agent included in the sealing part includes an O-ring, and preferably includes one selected from NBR O-ring, HNBR O-ring, VITON O-ring, and EPDM O-ring. do.

Hereinafter, a method of stacking the stack 1000 will be described in detail. The first step of laminating the PVC head plate 200 on the end plate 100 to stack the stack 1000, the second step of laminating the first current collector 300 on the PVC head plate 200, the A third step of stacking the first positive electrode plate (B1, bipolar plate, BP) on the first current collector 300, and a fourth step of stacking the cells 500, 600, and 700 on the first positive electrode plate (B1, bipolar plate, BP). Step 5 of stacking a second positive electrode plate (B2, bipolar plate, BP) on the cells 500, 600, and 700, stacking a second current collector 800 on the second positive electrode plate (B2, bipolar plate, BP) and a sixth step of stacking a central electrolyte distribution pipe on the second current collector.

The first step is to laminate the PVC head plate 200 on the end plate 100, characterized in that the front part of the end plate 100 is laminated so that the front part of the PVC head plate 200 contacts.

The second step is to laminate the first current collector 300 on the PVC head plate 200, and laminate the first collector 300 on the central portion 210 of the rear surface of the PVC head plate 200'. It is characterized in that it is fixed by.

The third step is characterized in that the first positive electrode plate (B1) is stacked on the first current collector 300.

The fourth step is the step of laminating the anode flow frame on the first anode plate B1, inserting a first electrode into the front portion of the anode flow frame, laminating a separator on the first electrode, The step of stacking the front part of the cathode flow frame so that the front part of the cathode flow frame is in contact with the front part of the anode flow frame and inserting a second electrode into the rear part of the cathode flow frame.

In detail, the fourth step of stacking the cells is stacking the cells on the first positive electrode plate B1 so that the rear part 510 ′ of the first positive electrode flow frame contacts, the front part of the first positive electrode flow frame The step of laminating the first electrode 520 on the 510, the step of laminating the separator 530 on the first electrode 520, the front part of the first anode flow frame on the separator 530 ( 510) and the front part 550 of the first cathode flow frame to be in contact with each other and inserting the second electrode 540 into the rear part 550 'of the first cathode flow frame. to be

At this time, the front part 510 of the first anode flow frame and the front part 550 of the first cathode flow frame are stacked so that they come into contact with each other, so that the right fastening part 514 of the front part 510 of the first anode flow frame ) is stacked so that the left fastening part 555 of the front side of the first cathode flow frame is in contact with each other, and the respective electrolytes flowing to the flow frame that are in contact with each other flow through different passages.

Furthermore, the fourth step of stacking the cells is to stack the cells consecutively, and is characterized in that N cells are stacked. Specifically, the fourth step of stacking the cells to perform the fifth step is characterized in that the cells are stacked consecutively.

That is, cells are continuously stacked on the back side 550′ of the first cathode flow frame into which the second electrode 540 is inserted, and between the continuously stacked cells (see FIG. 2, 500 and 600 Between , between 600 and 700), it is preferable to include a bipolar plate (BP).

Specifically, stacking a third positive electrode plate (B3) on the second electrode 540 to continuously stack the cells, the rear part 610' of the second positive flow frame on the third positive electrode plate (B3) ) is in contact, inserting the first electrode 620 into the front part 610 of the second anode flow frame, stacking the separator 630 on the first electrode 620, Laminating the front part 610 of the second anode flow frame and the front part 650 of the first cathode flow frame on the separation membrane 630 so that they come into contact with each other and on the rear part 650 of the first cathode flow frame It is preferable to insert the second electrode 640 into.

At this time, it is preferable to repeatedly stack the above steps to continuously stack the cells, and the cathode flow frame of the last cell is the second cathode flow frame 750 instead of the first cathode flow frames 550 and 650 It is preferable to laminate them.

In other words, the positive flow frame included in the cell in contact with the first positive electrode plate B1 is the first positive electrode flow frame 510, and the positive flow frame included in the cell not in contact with the first positive electrode plate B1 is characterized in that the second anode flow frame (610, 710).

In addition, the cathode flow frame included in the cell in contact with the second positive electrode plate B2 is the second cathode flow frame 750, and the cathode flow frame included in the cell not in contact with the second positive electrode plate B2 is It is characterized in that it includes a first cathode flow frame (550, 650).

Furthermore, poles of the flow frame contacting the first positive electrode plate B1 and the second positive electrode plate B2 are different from each other. That is, if the flow frame contacting the first positive electrode plate (B1) is a positive flow frame, it is preferable that the flow frame contacting the second positive electrode plate (B2) is a negative flow frame, and contacting the first positive electrode plate (B1) It is characterized in that the flow frame is a cathode flow frame, and the flow frame contacting the second positive electrode plate (B2) is an anode flow frame. For example, if a cell formed to contact the first positive electrode plate is a first positive flow frame, a cell contacting the second positive electrode plate is a second negative flow frame, and a cell formed to contact the first positive electrode plate is a first negative flow frame. , the cell in contact with the second positive electrode plate is preferably the second positive electrode flow frame.

Here, the classification of the first anode flow frame, the second anode flow frame, the first cathode flow frame, and the second cathode flow frame is based on the location where they are placed, and the first anode flow frame 510 disposed outside the Except for the second cathode flow frame 750, the second anode flow frames 610 and 710 and the first cathode flow frames 550 and 650 have the same shape.

Meanwhile, in the step of stacking the first anode flow frame 510, an outer sealing agent and a manifold sealing agent are inserted into the front portion 510 of the first anode flow frame, and the rear portion of the first anode flow frame ( 510') characterized by inserting a positive electrode sealing agent.

In addition, the step of stacking the second anode flow frames 610 and 710 includes inserting an outer sealing agent and a manifold sealing agent into the front portions 610 and 710 of the second anode flow frame, and It is characterized in that a positive plate sealing material and an outer sealing material are inserted into the rear parts 610' and 710' of the frame.

In addition, the step of stacking the first cathode flow frames 550 and 650 includes inserting an outer sealing material, a manifold sealing material, and a separator sealing material into the front surfaces 550 and 650 of the first cathode flow frame, It is characterized in that a positive electrode plate (bipolar plate, BP) sealing agent and an outer sealing agent are inserted into the rear surfaces 550' and 650' of the first cathode flow frame.

In addition, in the step of stacking the second cathode flow frame 750, an outer sealing agent, a manifold sealing agent, and a separator sealing agent are inserted into the front portion 750 of the second cathode flow frame, and the second cathode flow It is characterized in that a positive plate (bipolar plate, BP) sealing material is inserted into the rear part 750' of the frame.

Meanwhile, the fourth step of stacking the cells includes forming the anode flow frame and the cathode flow frame before performing the cell stacking step.

Electrolyte passages 511, 551, 611, and 751 of the first anode flow frame 510, the second anode flow frame 610 and 710, the first cathode flow frame 550 and 650, and the second cathode flow frame 750 The first anode flow frame 510, the second anode flow frame 610, 710, the first cathode flow frame 550, 650, and the second cathode It is characterized in that the flow frame 750 is formed.

At this time, it is preferable that the process of attaching the cover plate to the electrolyte passage is performed before stacking the cells.

The fifth step is to stack the second positive electrode plate B2 on the cell, and it is preferable to arrange the second positive electrode plate B2 to contact the rear surface 750′ of the second negative electrode flow frame.

The sixth step is characterized in that the second current collector 800 is laminated on the second positive electrode plate (B2), and the seventh step is the central electrolyte distribution pipe ( 900) is characterized by laminating.

The method of stacking the stack is characterized in that N cells are continuously stacked on one surface of the central electrolyte distribution pipe 900, and N cells are continuously stacked on the other surface of the central electrolyte distribution pipe 900. .

Specifically, the step of stacking the cells on the other side of the central electrolyte distribution pipe 900 with the central electrolyte distribution pipe 900 as the center may be stacked in the reverse order of the step of stacking the cells on one side of the central electrolyte distribution pipe 900. can That is, the poles of the cells stacked on one side of the central electrolyte distribution pipe 900 and the poles of the cells stacked on the other side may be identically stacked.

For example, when stacking cells on one surface of the central electrolyte distribution pipe 900 in reverse order to stacking cells on the other surface of the central electrolyte distribution pipe 900, the second current collector 800 The step of stacking, the step of laminating the second current collector 800 and the detailed second positive electrode plate B2, the step of stacking the plurality of cells 400 on the second positive electrode plate B2, the step of stacking the plurality of cells 400 on the second positive electrode plate B2 Laminating the first negative plate B1, stacking the first current collector 300 on the first positive electrode plate B1, and stacking the PVC head plate 200 on the first current collector 300 and the step of laminating the end plate 100 on the PVC head plate 200.

At this time, when cells are stacked on the other surface of the central electrolyte distribution pipe 900 in reverse order, the cells on both sides of the central electrolyte distribution pipe 900 have a mirror image structure. Therefore, as shown in the schematic diagram of FIG. 17, the location of the inlet and outlet for the electrolyte to flow must be changed, and the anode flow frame and cathode flow frame disposed on one side for electrolyte flow are disposed on one side. It must be manufactured to have the structure and mirror image of the flow frame.

That is, a mirror image first anode flow frame and a mirror image first anode flow frame, a second anode flow frame and a mirror image second anode flow frame, a first cathode flow frame and a mirror image first cathode flow frame, a second cathode flow frame and a mirror image second anode flow frame. 2 cathode flow frames, i.e. 8 frames each are required.

In addition, as shown in FIG. 18, when a mirror image flow frame is manufactured and one side and the other side of the central electrolyte distribution pipe 900 are laminated in reverse order, the poles in contact with the central electrolyte distribution pipe 900 are the same, and they are serially Connect the anode at the left end formed on one side of the central electrolyte distribution pipe 900 and the cathode directly in contact with the other side of the central electrolyte distribution pipe, and the anode at the right end on the other side of the central electrolyte distribution pipe and the center It is necessary to connect the negative electrode directly in contact with one surface of the electrolyte distribution pipe, and the length of the wire becomes longer, and resistance may increase accordingly.

Accordingly, the step of stacking the cells on the other side of the central electrolyte distribution pipe with the central electrolyte distribution pipe 900 as the center may be stacked in the same order as the step of stacking the cells on one side of the central electrolyte distribution pipe. That is, the poles of cells stacked on one surface and cells stacked on the other surface around the central electrolyte distribution pipe 900 may be stacked differently.

For example, stacking a first current collector 300 on the other surface of the central electrolyte distribution pipe 900 to complete the stack by stacking cells on the other surface of the central electrolyte distribution pipe 900; Stacking a first positive electrode plate (B1) on the current collector 300, stacking a plurality of cells 400 on the first positive electrode plate (B1), and stacking a second positive electrode plate (B2) on the plurality of cells ), laminating the second current collector 800 on the second positive electrode plate B2, laminating the PVC head plate 200 on the second current collector 800, and the PVC head plate It may be laminated in the step of laminating the end plate 100 on the (200).

As the cells are stacked on one side and the other side of the central electrolyte distribution pipe 900 in the same order, it is not necessary to manufacture mirror-shaped anode flow frames and cathode flow frames for stacking on the other side.

In addition, as shown in FIG. 19, as the cells are stacked in the same order on one side and the other side of the central electrolyte distribution pipe 900, all the cells in the stack 1000 are connected in series, and the wire connection is shortened to increase the resistance impact may be less.

On the other hand, after stacking the stack, it is characterized in that bolts and nuts are fastened to the end plate 100 for sealing and compressed by a press. At this time, the press pressure is preferably 0.5MPa.

Hereinafter, the present invention will be described in detail through Examples and Experimental Examples. However, the following Examples and Experimental Examples are merely illustrative of the present invention, and the present invention is not limited by the following Examples and Experimental Examples.

20 is an image of a redox flow battery in which 80 cells are stacked according to an embodiment.

Referring to FIG. 20, one end plate is placed on the floor and stacking is started. Each component is laminated in the order of lamination. Considering the sealing between each component, press once in half the number of laminations up to the central electrolyte distribution pipe, and after stacking up to the central electrolyte distribution pipe, compress with a press, Even after that, press compression is performed to finally complete the bolt and nut fastening to complete the stack assembly.

21 is a graph showing cycle-by-cycle efficiency of a redox flow battery stack according to an embodiment, and FIG. 22 is a graph showing cycle-by-cycle charge/discharge efficiency and capacity of a redox flow battery stack according to an embodiment.

21 and 22, it can be confirmed that the performance and electrolyte capacity of the redox flow battery stack are maintained even when the cycle is increased.

Referring to FIG. 21 , it can be seen that there is almost no degradation in performance. Also, referring to FIG. 22 , the charge/discharge capacity is indicated by the amount of electrolyte. Charge and discharge are performed according to the amount of vanadium ions in the electrolyte. If the amount of vanadium ions is kept constant, the capacity is constant. When leakage occurs, the amount of electrolyte and the amount of vanadium ions decrease, so the charging and discharging time is reduced, and the reduction in the time is small.

It is believed that this is because the leakage preventing effect is excellent by stacking the stacks according to the present invention.

In this specification, only a few examples of various embodiments performed by the present inventors are described, but the technical idea of the present invention is not limited or limited thereto, and can be modified and implemented in various ways by those skilled in the art, of course.

Claims (8)

In the method of stacking the stack around the central electrolyte distribution pipe,
A first step of laminating a PVC head plate on an end plate;
A second step of laminating a first current collector on the PVC head plate;
a third step of stacking a first positive electrode plate (bipolar plate, BP) on the first current collector;
a fourth step of stacking cells on the first positive electrode plate (bipolar plate, BP);
A fifth step of stacking a second positive electrode plate (bipolar plate, BP) on the cell;
a sixth step of stacking a second current collector on the second positive plate (bipolar plate, BP); and
A seventh step of laminating a central electrolyte distribution pipe on the second current collector;
In the fourth step of stacking the cells,
laminating the anode flow frame on the first anode plate (bipolar plate, BP);
inserting a first electrode into the front portion of the anode flow frame;
stacking a separator on the first electrode;
laminating a cathode flow frame on a front side of the anode flow frame; and
Including; inserting a second electrode into the rear surface of the cathode flow frame,
Laminating the cathode flow frame
Laminating a first cathode flow frame and laminating a second cathode flow frame,
The step of laminating the first cathode flow frame,
Inserting an outer sealant, a manifold sealant, and a separator sealant into the front portion of the first cathode flow frame,
Inserting a positive electrode (bipolar plate, BP) sealing agent and an outer sealing agent into the rear part of the first negative electrode flow frame,
Stacking method of redox flow battery with enhanced sealing. According to claim 1,
The fourth step of stacking the cells is
Forming the anode flow frame and the cathode flow frame,
Stacking method of redox flow battery with enhanced sealing. According to claim 2,
Forming the anode flow frame and the cathode flow frame,
Bonding the electrolyte flow path of the anode flow frame and the cathode flow frame with a cover plate,
Stacking method of redox flow battery with enhanced sealing. According to claim 1,
The fourth step of stacking the cells is to stack the cells consecutively,
To include a positive electrode plate (bipolar plate, BP) between the continuously stacked cells and cells,
Stacking method of redox flow battery with enhanced sealing. According to claim 1,
The cell formed to contact the first positive electrode plate includes a first positive flow frame and a first negative flow frame,
Stacking method of redox flow battery with enhanced sealing. According to claim 2,
The cell formed to contact the second positive plate includes a second positive flow frame and a second negative flow frame,
Stacking method of redox flow battery with enhanced sealing. According to claim 1,
If the cell formed to contact the first positive electrode plate is a first positive electrode flow frame, the cell contacting the second positive electrode plate is a second negative electrode flow frame,
If the cell formed to contact the first positive electrode plate is the first negative flow frame, the cell contacting the second positive electrode plate is the second positive electrode flow frame.
Stacking method of redox flow battery with enhanced sealing. According to claim 1,
The method of stacking the stack is that N cells are successively stacked on one surface of the central electrolyte distribution tube and N cells are continuously stacked on the other surface of the central electrolyte distribution tube.
Stacking method of redox flow battery with enhanced sealing.

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