KR20170076514A - Redox flow battery system having reduced shunt loss - Google Patents

Abstract

The present invention relates to a redox flow cell including an electrolyte storage tank and a stack module for receiving an electrolyte solution from an electrolyte storage tank, wherein M unit cells are stacked to form a unit stack, and N unit stacks are connected in series And the stack module is connected to the electrolyte solution supply pipe and the electrolyte solution recovery pipe, and the electrolyte solution supply pipe and the electrolyte solution recovery pipe are connected to the electrolyte solution storage tank, and the electrolyte solution supply pipe and the electrolyte solution recovery pipe are connected to the electrolyte solution storage tank, And a branch piping branching to N branches in the main piping and connected to each unit stack, wherein the length of the branch piping connected to each unit stack is M * (0.25 to 0.75) m.

Description

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

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a redox flow battery, and more particularly, to a redox flow battery system that reduces self-discharge due to a shunt current generated between unit stacks.

The Redo Flow Battery is a device that converts the chemical energy of an electrolyte solution into electric energy through a battery cell.

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

As shown in the figure, a redox flow cell stores a positive electrode electrolyte in a positive electrode electrolyte storage tank 110, and a negative electrode electrolyte in a negative electrode electrolyte storage tank 112.

The positive electrode cell 102A and the negative electrode cell 102B of the cell 102 are connected to the positive electrode electrolytic solution storage tank 110 and the negative electrode electrolytic solution storage tank 112 through the positive electrode electrolyte pump 114 and the negative electrode electrolyte pump 116, ≪ / RTI >

In the anode cell 102A, electrons move through the electrode 106 in accordance with the operation of the power source / load 118, thereby causing an oxidation / reduction reaction. Similarly, in the cathode cell 102B, the movement of electrons through the electrode 108 occurs according to the operation of the power source / load 118, so that an oxidation / reduction reaction occurs. After the oxidation / reduction reaction, the cathode electrolyte and the cathode electrolyte are circulated to the anode electrolyte storage tank 110 and the cathode electrolyte storage tank 112.

On the other hand, the anode cell 102A and the cathode cell 102B are separated by the ion exchange membrane 104 through which ions can pass. Accordingly, ion movement, that is, crossover, may occur between the anode cell 102A and the cathode cell 102B. That is, during the charging / discharging process of the redox flow cell, the positive electrode electrolyte ions of the positive electrode cell 102A move to the negative electrode cell 102B and the negative electrode electrolyte ions of the negative electrode cell 102B can move to the positive electrode cell 102A.

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

The current flowing between the battery cells through the electrolyte solution sharing path is called a shunt current. Shunt currents occur inside or between stacks and cause self-discharge of the stack. Reduced energy stored in the stack even in a standby state in which redox flow cells are not operated by self-discharge.

The present invention reduces shunt loss occurring between unit stacks of a redox flow cell, thereby reducing self-discharge of the redox flow battery and improving overall energy efficiency.

An object of the present invention is to reduce shunt loss occurring between unit stacks of redox flow cells.

Another object of the present invention is to provide a structure of an electrolyte solution supply pipe and an electrolyte solution recovery pipe capable of reducing shunt loss occurring between unit stacks of a redox flow cell.

According to an aspect of the present invention, there is provided a redox flow cell including an electrolyte storage tank and a stack module that receives an electrolyte solution from an electrolyte storage tank, the redox flow cell comprising M unit cells stacked to form a unit stack, N is connected in series to constitute a stack module, the anode electrolyte storage tank and the cathode electrolyte storage tank and the stack module are connected by an electrolyte supply pipe and an electrolyte solution return pipe, and the electrolyte solution supply pipe and the electrolyte solution return pipe are connected to each electrolyte A main pipe connected to the storage tank; and a branch pipe branched into N branches and connected to each unit stack by the main pipe. The length of the branch pipe connected to each unit stack is M * (0.25 ~ 0.75) m, Thereby providing a battery.

At this time, the product of the diameter of the branch pipe and the number of branch pipes (N) preferably ranges from 1.5 to 2.0 times the diameter of the main pipe.

It is also preferable that the ratio of the length of the electrolyte supply pipe connected to each unit stack and the length of the electrolyte recovery pipe is constant.

It is also preferable that the sum of the pipe lengths connecting the respective unit stacks and the anode electrolyte storage tanks and the sum of the pipe lengths connecting the unit stacks and the cathode electrolyte storage tanks are set to be the same.

In addition, the shunt resistor can be provided on the flow path of the branch pipe to further reduce the shunt loss.

The unit stack may include a mid-block for dividing the stacked unit cells into a small group stack, and the branch pipe may be connected to the mid-block.

At this time, a plurality of the midblocks may be provided, and a stack connecting pipe may be provided which is connected to the midblock by a second branch in the branch pipe.

The redox flow cell according to the present invention provides a piping structure capable of reducing shunt loss, thereby reducing the shunt loss occurring between unit stacks without requiring a complicated control device.

In addition, the redox flow battery according to the present invention improves the efficiency of the entire redox flow battery system in consideration of pump loss and shunt loss, which are in conflict with each other.

1 is a schematic diagram showing a configuration of a redox flow cell.
2 is a conceptual diagram for explaining shunt loss occurring in a redox flow cell.
3 is a block diagram illustrating a redox flow cell having reduced shunt loss according to an embodiment of the present invention.
4 is a graph showing changes in shunt loss and pump loss according to the length of piping in the redox flow battery system.
5 shows a redox flow cell according to another embodiment of the present invention.
6 shows an example of a unit stack in the redox flow cell according to the present invention.
7 illustrates a unit stack of a redox flow cell according to another embodiment of the present invention.

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

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout.

2 is a conceptual diagram for explaining shunt loss occurring in a redox flow cell.

The redox flow cell produces power using a redox reaction between a cathode electrolyte and an anode electrolyte, with the ion exchange membrane sandwiched therebetween. Since a voltage generated in one unit cell is low, a plurality of unit cells are stacked to form a stack It is generally used.

The stack is formed by stacking a plurality of unit cells, and the electrolytic solution is supplied to each unit cell through a common supply passage as shown in the figure. Although not shown, Is recovered.

The shunt current is generated when the electrode unit of the unit cell constituting the stack is connected to the electrode unit of the adjacent cell and the electrolytic solution. The electrode of each unit cell is connected to the cell voltage The voltage difference will be generated as much as the voltage difference. This occurs because the unit cells constituting the stack are connected in series with each other.

Therefore, as the number of stacked unit cells increases, the voltage difference gradually increases. If one cell voltage is 1.2V and a total of 10 cells are connected in series, the voltage difference between the electrodes located at both ends becomes 10.8V (1.2V * 9).

The shunt current changes according to the voltage difference of the cell and the electrolyte resistance.

The shunt current generated in the stack or between the stacks is composed of a complicated electric circuit model that occurs in multiple cells in a complex manner, but can be simply expressed as follows.

Shunt current: I = ΔV / R _s

Shunt _{resistance: R s = R * L /} A

* R _s : Shunt resistance

* R: electrolyte resistivity,

* L: length of electrolytic solution path between cell electrodes

* A: Cross-sectional area of electrolyte path between cell electrodes

To reduce the shunt current when a particular electrolyte is used, the voltage difference must be reduced or the shunt resistance must be increased.

However, since the voltage is controlled by the number of stacked unit cells, it is possible to reduce the voltage difference by dividing the entire stack module into unit stacks and connecting each unit stack in series rather than stacking the stack modules at once.

In addition, the shunt resistor may increase the method of decreasing the path cross-sectional area of the electrolyte or increasing the path length of the electrolyte. The path cross-sectional area and path length of the electrolyte can be controlled by varying the diameter and length of the pipe connecting the electrolyte storage tank and the stack.

3 is a block diagram illustrating a redox flow cell having reduced shunt loss according to an embodiment of the present invention.

As shown in the figure, the redox flow battery includes a positive electrode electrolyte storage tank 110 for storing a positive electrode electrolyte, a negative electrode electrolyte storage tank 112 for storing a negative electrode electrolyte, a stack module 200 ).

The present invention provides a structure for dividing the stack module 200 into unit stacks 210 to reduce shunt losses.

Splitting the stack module 200 into unit stacks can reduce the voltage difference that affects the shunt current.

Each of the electrolyte storage tanks 110 and 112 and the stack module 200 are connected to the electrolyte solution supply tubes 300 and 300 'and the electrolyte solution recovery tubes 400 and 400'.

The positive electrode electrolytic solution stored in the positive electrode electrolyte storage tank 110 is supplied in parallel to each unit stack 210 of the stack module 200 through the electrolyte supply pipe 300 and the positive electrode electrolyte discharged from each unit stack 210 And then circulated through the electrolyte recovery pipe 400 to the anode electrolyte storage tank 110 again.

Likewise, the negative electrode electrolytic solution stored in the negative electrode electrolyte storage tank 112 is supplied in parallel to each unit stack 210 of the stack module 200 through the electrolyte supply pipe 300 ', and discharged from each unit stack 210 The negative electrode electrolyte is circulated to the negative electrode electrolyte storage tank 112 through the electrolyte recovery pipe 400 '.

The unit stack 210 is formed by stacking M unit cells, and each unit stack 210 is electrically connected in series.

The unit stacks 210 constituting the stack module 200 are connected to each other in series.

For example, if the unit cell has a voltage of 1.0V, the unit stack 210 is composed of 40 unit cells, and the stack module 200 is composed of 6 unit stacks, the voltage of the individual unit stack 210 Becomes 40V, and the voltage of the stack module becomes 240V.

If the stack module 200 is not divided into the unit stack 210, the voltage difference causing the shunt current is 240 V, but since the unit stack 210 is divided into six unit stacks 210, the voltage difference causing the shunt current is 40 V . Of course, even if the stack module 200 is divided into the unit stack 210, if the pipelines between the unit stacks 210 are connected in parallel, the total voltage difference is equal to 240V.

By dividing the stack module 200 into unit stacks 210, it is possible to reduce the shunt loss, the convenience of the flow rate adjustment, the ease of assembling, the ease of the pressure drop design, and the maintenance convenience.

Referring to the electrolyte supply pipes 300 and 300 ', the electrolyte supply pipes 300 and 300' include main pipes 310 and 310 'connected to the electrolyte storage tanks 110 and 112, and the number of unit stacks 210 in the main pipes 310 and 310' (Six in the case of the illustrated embodiment) and connected to each unit stack 210.

In the case of the electrolyte recovery pipes 400 and 400 'as well, the main pipes 410 and 410' and the branch pipes 420 and 420 'are provided in the same manner as the electrolyte supply pipes 300 and 300'.

Although the piping is shown in a block diagram for convenience of illustration, the lengths of the branch pipes 320 and 320 'may appear to be different from each other, but it is preferable that the lengths of the branch pipes 320, 320', 420 and 420 ' Do.

This is to allow the electrolyte to be uniformly supplied to each unit stack 210.

Ideally, each should be set identically, but for most actual system piping, due to installation conditions, conditions, etc.

4 is a graph showing changes in shunt loss and pump loss according to the length of piping in the redox flow battery system.

As shown in the drawing, when the length of the pipe is increased, the electrical resistance between the unit stacks is increased, so that the shunt loss is reduced.

However, in terms of pump loss, as the length of the piping increases, the resistance of the fluid increases and the pump loss increases.

In other words, the shunt current loss and the pump loss have a trade off relationship with each other.

And to provide a piping structure that can optimize BOP loss, which is the sum of pump loss and shunt loss.

Referring again to FIG. 3, the length of the entire piping (the sum of the length of the main pipe and the length of the branch pipe) is a very important factor in terms of the pump loss. In terms of shunt loss, The length of the branch pipes 320, 320 ', 420, 420' to which the flow paths of the branch pipes 320, 320 ', 420, 420'

The shunt loss is due to the shunt current, and the shunt current is related to the voltage difference as discussed above. The higher the voltage of the unit stack 210, the greater the amount of shunt current, which increases the shunt loss.

Therefore, the length of the branch pipe is related to the number of stacked unit cells constituting the unit stack 210.

The redox flow battery according to the present invention is characterized in that the lengths of branch pipes branched to each unit stack 210 are the same.

This is to ensure that the shunt losses occurring in each unit stack 210 can be maintained uniform by allowing the unit stacks 210 to have the same electrical resistance value and to be connected.

In other respects, when the lengths of the branch pipes 320, 320 ', 420, 420' are different from each other, a variation occurs in the flow rate and flow rate of the electrolytic solution supplied to each unit stack 210, A problem that the operation can not be performed occurs.

In the case where the unit stack is formed by stacking M cells, the length of the branch pipe connected to each unit stack is preferably in the range of M * (0.25 to 0.75) m.

When the lengths of the branch pipes 320, 320 ', 420 and 420' are less than M * 0.25 m, the shunt resistance of the branch pipes 320, 320 ', 420 and 420' is low and the shunt loss is excessively increased. ') Exceeds M * 0.75m, the pump loss due to the extension of the pipe length increases rather than the shunt loss reduction effect due to the increase of the shunt resistance, resulting in a deterioration of the overall system efficiency.

In terms of pump loss, the product of the diameter of the branch pipes 320, 320 ', 420, 420' and the number of branch pipes is preferably in the range of 1.5 to 2.0 times the diameter of the main pipe.

The electrolytic solution is divided into branch pipings 320, 320 ', 420 and 420' by the number of unit stacks 210 after passing through the main pipe. The number of the branch pipings 320, 320 ', 420 and 420' When the product of the diameters of the branch pipes 320, 320 ', 420 and 420' is less than 1.5 times the diameter of the main pipes 310, 310 ', 410 and 410', it is difficult to secure the pressure to the branch pipes 320, 320 ', 420 and 420' And the diameter of the branch pipe exceeds twice the diameter of the main pipe, there arises a problem that the flow velocity is rapidly reduced while being branched.

Meanwhile, it is preferable that the ratio of the length of the electrolyte supply pipes 300 and 300 'connected to the respective unit stacks 210 and the length of the electrolyte recovery pipes 400 and 400' is constant.

Here, the length of the electrolyte supply pipes 300 and 300 'means the sum of the length of the main pipe and the length of one branch pipe, which means the length of the electrolyte flowing from the electrolyte storage tank to the unit stack, 'Have the same meaning.

When the ratio of the length of the electrolyte supply pipe and the length of the electrolyte recovery pipe in each unit stack 210 becomes constant, the electrolyte supplied to each unit stack 210 has the same flow resistance, The electrolyte can be uniformly supplied to the stack 210.

The sum of the pipe lengths connecting the unit stacks 210 and the anode electrolyte storage tanks 110 and the sum of the pipe lengths connecting the unit stacks 210 and the cathode electrolyte storage tanks 112 are the same .

This is to balance the positive and negative electrode electrolytes fed into each unit stack.

5 shows a redox flow cell according to another embodiment of the present invention.

The present embodiment is characterized in that the shunt resistor 330 is provided on the flow path of the branch pipe. The shunt resistor 330 functions to block the branch pipe or to reduce the cross-sectional area of the branch pipe locally to increase the electrical resistance.

Although the shunt resistor 330 is installed in the branch pipes 320 and 320 'of the electrolyte supply pipes 300 and 300' in the figure, the shunt resistors are installed in the branch pipes 420 and 420 'of the electrolyte solution recovery pipes 400 and 400' And a shunt resistor may be provided for both branch pipes on both sides.

The shunt resistor 330 may be of a type that maintains a constant state at all times or may be of a type that operates variably at the time of operation and at the time of operation stop.

In the case of a type that always maintains a constant state, the sectional area of the branch pipe can be reduced locally, thereby increasing the electrical resistance of the branch pipe.

And may be constituted by an open / close valve in the case of a variably operating type, and may be operated to close the open / close valve at the time of stop of operation. It can be operated to maintain the open state to prevent pump loss from increasing during operation and to close the branch piping to reduce shunt loss during shutdown.

6 shows an example of a unit stack in the redox flow cell according to the present invention.

Generally, the unit stack has a form in which unit cells are stacked between a pair of end plates, and the electrolyte solution supply pipe and the electrolyte solution return pipe are connected to the end plate.

The present embodiment is characterized in that a mid block 215 is provided in a unit stack 210 in which unit battery cells are stacked between end plates 212 so that the branch pipe 320 of the electrolyte solution supply pipe, And the branch pipe (420) is connected to the mid block (215).

The midblocks are stacked between unit cells to divide the unit stack into small group stacks 216a and 216b. The divided small group stacks 216a and 216b are electrically connected in series.

For example, if a unit stack is formed by stacking 40 unit cells, it can be divided into two small group stacks 216a and 216b in which 20 unit cells are stacked using one midblock 215.

Since an electrolyte may not be uniformly supplied to each unit cell when an excessively large number of unit cells are stacked, a mid-block 215 may be provided in the unit stack to divide the stack into small groups in which a proper number of unit cells are stacked will be.

The arrangement of the midblocks 215 also has an advantageous effect in terms of reducing shunt loss. This is because, when the midblocks 125 are disposed, the electrolyte connected to the unit cells in parallel is separated by the midblocks 125, thereby increasing the electrical resistance.

The midblock 215 is connected to the branch pipes 320 and 420 so as to distribute the electrolyte flowing into the branch pipes into a small group stack on both sides of the midblock.

7 illustrates a unit stack of a redox flow cell according to another embodiment of the present invention.

As shown, one unit stack may include a plurality of midblocks 215 and 217. [

In the illustrated embodiment, three midblocks are provided and the unit stack is divided into four subgroup stacks 216a, 216b, 216c, and 216d. At this time, no piping is connected to the mid-block 217 at the center.

By using the midblock, a unit stack having more unit cells can be formed, and the unit stack can be further divided into subgroups to distribute the electrolyte solution through the midblocks, thereby more uniformly supplying the electrolytic solution to each unit cell. It is also advantageous in terms of shunt loss reduction as described above.

As shown in the drawing, when a plurality of midblocks are provided in one unit stack, it is preferable that stack connecting pipes 340 and 440 branched from the branch pipe and connected to the midblock 215 are provided. At this time, it is preferable that the respective stack connecting pipes 340 and 440 have the same length and the same diameter as the supply pipe and the discharge pipe having the same length as the branch pipe.

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

110: positive electrode electrolyte tank
112: cathode electrolyte tank
200: stack module
210: Unit stack
212: End plate
215, 217: midblock
216a, 216b, 216c, 216d:
300, 300 ': electrolyte supply piping
310, 310 ': Main valve
320,320 ': Branch piping
330: Shunt resistor
400, 400 ': Electrolyte recovery pipe
410, 410 ': Main valve
420, 420 ': Branch piping

Claims (7)

1. A redox flow cell comprising an electrolyte storage tank and a stack module for receiving an electrolyte solution from an electrolyte storage tank,
M unit cells are stacked to form a unit stack, N units of the unit stacks are connected in series to constitute a stack module,
The positive electrode electrolyte storage tank, the negative electrode electrolyte storage tank and the stack module are connected to the electrolyte solution supply pipe and the electrolyte solution recovery pipe,
Wherein the electrolyte supply pipe and the electrolyte solution return pipe each include a main pipe connected to each of the electrolyte storage tanks and a branch pipe branching into N branches in the main pipe and connected to each unit stack,
The redox flow cell system with the branch piping connected to each unit stack is M * (0.25 ~ 0.75) m.
The method according to claim 1,
Wherein the product of the diameter of the branch pipe and the number of branch pipes (N) is in the range of 1.5 to 2.0 times the diameter of the main pipe.
The method according to claim 1,
Wherein a ratio of the length of the electrolyte supply pipe connected to each unit stack and the length of the electrolyte recovery pipe is constant.
The method according to claim 1,
The sum of the pipe lengths connecting each unit stack and the anode electrolyte storage tank
Wherein the sum of the pipe lengths connecting the unit stack and the cathode electrolyte storage tank is the same.
The method according to claim 1,
And the shunt resistor is provided on the flow path of the branch pipe.
The method according to claim 1,
The unit stack
And a midblock for dividing the stacked unit cells into a small group stack, wherein the branch pipe is connected to the midblock.
The method according to claim 6,
A plurality of said midblocks,
And a stack connecting pipe branched from the branch pipe and connected to the midblock.

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