KR20230064807A - double injection mould for stack plate of redox flow battery - Google Patents

Abstract

The present invention relates to a double composite injection mold for manufacturing a redox flow battery stack plate structure, the mold including: a first mold having a first molding groove which is formed thereon, and supports injection molding of a stack plate having a quadrilateral empty space at the center thereof and having a first and a second through-hole which are provided at the corner portions in the diagonal direction thereof, respectively, and support water flow and stack coupling; and a second mold which is engaged with the first mold, has a second molding groove which is formed thereon and forms a cavity for injection-molding the stack plate together with the first molding groove, and is configured such that each leakage prevention guide ring, which is mounted to prevent leakage, can be inserted thereinto and thus accommodated therein, in a state of being coupled to be mutually stacked along the edge line of the quadrilateral empty space and the first and the second through-hole. According to the double composite injection mold for manufacturing a redox flow battery stack plate structure, a leakage prevention guide ring can be molded integrally at once on a stack plate so that assembly efficiency can be improved.

Description

Double composite injection mold for stack plate structure manufacturing of redox flow battery {double injection mold for stack plate of redox flow battery}

The present invention relates to a double composite injection mold for manufacturing a stack plate structure of a redox flow battery, and more particularly, a redox flow battery capable of integrally molding a leak-preventing guide ring on a stack plate to improve assembly properties. It relates to a double composite injection mold for manufacturing a stack plate structure.

A large-capacity energy storage device is attracting attention as an alternative to overcome the variability of power production and the inconsistency of supply and demand timing, and among them, the redox flow battery is attracting attention.

Redox flow battery is a system in which the active material contained in the electrolyte is charged and discharged by redox (reduction-oxidation), unlike conventional secondary batteries that store electrical energy in an electrode containing an active material. It is an electrochemical storage device that directly stores the chemical energy of the active material as electrical energy.

Active materials that cause redox reactions include V, Fe, Cr, Ti, and Sn, and these metals are dissolved in a strong acid solution and used as an electrolyte. Materials used as solvents include sulfuric acid, hydrochloric acid, nitric acid, and organic electrolytes used in lithium secondary batteries. These electrolytes are stored in an external tank or located inside a stack.

In general, a stack of a redox flow battery includes a cathode cell (manifold) including a cathode electrode and a bipolar plate, a cathode cell (manifold) including a cathode electrode and a bipolar plate, and an ion separating the anode cell and the cathode cell. covers the exchange membrane. A plurality of anode cells and cathode cells may be stacked and used. At this time, a current collector and an end plate are placed on the outermost side of the cathode cell and the cathode cell in an outward direction, respectively.

Redox flow batteries have been variously disclosed, such as Korean Patent Application No. 10-2012-0094334.

On the other hand, stack plates that form the anode cell and the cathode cell of the redox flow battery and are stacked with each other are usually injection-molded in the form of a sheet and then in a state in which they are tightly coupled to each other through through-holes formed to penetrate the edge area to prevent leakage. The subsequent assembly work of assembling the circular leak-preventing guide ring is performed. In addition, in order to prevent liquid leakage through the square space while the membrane, which is a separation film, is fixed and supported in the square empty space in the center of the stack plate, the leakage prevention guide ring in the shape of a square frame is subsequently assembled. The downside is that it takes a lot of time.

The present invention was invented to improve the above problems, and in detail, provides a double composite injection mold for manufacturing a stack plate structure of a redox flow battery, which can be provided by integrally molding a leak-preventing guide ring on a stack plate. There is a purpose.

In order to achieve the above object, the double composite injection mold for manufacturing a redox flow battery stack plate structure according to the present invention has a square square empty space in the center and a first portion supporting water flow and stack coupling at diagonal corner portions, respectively. and a stack plate having a second through hole, a stack having a leak prevention guide ring mounted to prevent leakage in a state in which a stack plate having a second through hole and the first and second through holes of the stack plate are stacked and coupled to each other along an edge line of the square empty space. A dual composite injection mold for manufacturing a plate structure, comprising: a first mold formed with a first molding groove for supporting injection molding of the stack plate; The second molding groove is molded with the first mold and forms a cavity for injection molding of the stack plate together with the first molding groove, and the leak-preventing guide ring is inserted and received therein. A mold; is provided.

According to one aspect of the present invention, a runner is formed in the center of the first mold and distributes and supplies resin injected from a main inlet extending downward to the cavity, and the runner is provided with a runner from the lower end of the main inlet to the square a main transverse runner extending across the empty space along a first direction; a first central longitudinal runner extending from the lower end of the main inlet in both directions along the second direction perpendicular to the first direction to the square empty space and discharging resin at the end thereof; a first side longitudinal runner extending in both directions along the second direction in a first distribution area on the main horizontal runner spaced apart to the left with respect to the first central longitudinal runner and discharging resin at the longitudinal end; a first main crossing longitudinal runner disposed obliquely with respect to the first side longitudinal runner in the first distribution area, extending to cross in an X shape, and discharging resin at an end thereof; a first sub inclined longitudinal runner that obliquely extends from the first distribution area to an area between the first main crossing longitudinal runner and the first side longitudinal runner toward the first through hole; a second side longitudinal runner extending in both directions along the second direction in a second distribution area on the main transverse runner spaced apart to the right with respect to the first central longitudinal runner and discharging resin at a longitudinal end thereof; a second main crossing longitudinal runner disposed obliquely with respect to the second side longitudinal runner in the second distribution area and extending to intersect in an X shape to discharge resin at an end thereof; and a second sub cross longitudinal runner obliquely extending from the second distribution area to an area between the second main cross longitudinal runner and the second side longitudinal runner toward the second through hole.

Preferably, the leak-preventing guide ring is made of SEBS (Styrene ethylene butadiene styrene block copolymer) material.

According to the double composite injection mold for manufacturing a redox flow battery stack plate structure according to the present invention, the leak-preventing guide ring can be integrally molded on the stack plate at once, providing an advantage of improving assembly efficiency.

1 is a side view of a double composite injection mold for manufacturing a redox flow battery stack plate structure according to the present invention;
Figure 2 is an exploded perspective view showing the disassembled double composite injection mold of Figure 1,
Figure 3 is an exploded perspective view showing the first mold of Figure 2 is separated,
4 is a perspective view of the runner of FIG. 3 taken out;
5 is a perspective view showing a stack plate structure manufactured through the double composite injection mold of FIG. 1;
FIG. 6 is a perspective view of the stacked plate structure of FIG. 5 turned over so that the rear surface is exposed;

Hereinafter, a double composite injection mold for manufacturing a redox flow battery plate according to a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a side view of a double composite injection mold for manufacturing a redox flow battery stack plate structure according to the present invention, FIG. 2 is an exploded perspective view showing the double composite injection mold of FIG. 1 by disassembling it, and FIG. It is an exploded perspective view shown by separating the mold, and FIG. 4 is a perspective view showing the excerpt of the runner of FIG. 3 .

1 to 4, the dual composite injection mold 100 according to the present invention includes a first mold 110 and a second mold 120 that are mutually molded.

In the first mold 110, a first molding groove 101 for supporting injection molding of a stack plate structure forming a redox flow battery is formed on the inner surface of the opposite surface facing the second mold 120. .

Here, the stack plate structure has a rectangular square empty space 14 in the center as shown in FIGS. 5 and 6, and first and second through holes supporting water flow and stack coupling at the corners in the diagonal direction, respectively. (15) (16), the stack plate (12) of the rectangular plate shape, the first and second through holes (15) (16) of the stack plate (12), and the rectangular empty space (14) are mounted along the edge line, It has a structure having leak-preventing guide rings 21, 22, and 23 coupled to prevent leakage in the mutually stacked coupling state. Reference numerals 17 and 18 denote third and fourth through holes formed to pass through the corners of the stack plate 12 along directions crossing the directions connecting the first and second through holes 15 and 16 to each other. .

As can be seen through the rear surface, the first and second through holes 15 and 16 of the stack plate 12 are connected with flow channels communicating with the square empty space 14 respectively.

The first mold 110 is coupled to the first upper mold 111 in which the main inlet 131 is formed, and the lower part of the first upper mold 111, and the runner 140 is mounted therein, and the first mold groove is formed at the lower part. It is built with a first lower mold 112 in which 102 is formed.

The second mold 120 is molded with the first mold 110 and the second molding groove 102 forming a cavity 104 for injection molding of the stack plate 12 together with the first molding groove 101 It is formed on the upper surface and is formed so that the leak-preventing guide rings 21, 22, and 23 can be inserted and accommodated, respectively.

In this structure, the runner 140 for distributing and supplying the resin injected into the main inlet 131 extending downward at the center of the upper surface of the first mold 110 to the cavity 104 for forming the stack plate structure 10 is formed

Therefore, the leakage-preventing guide rings 21, 22, and 23 are inserted into the cavity 104, and the resin is supplied to the main injection port 131 in a state where the first and second molds 110 and 120 are molded together. A molded article in which the leak-preventing guide rings 21, 22, and 23 are integrated with the stack plate 12 is formed.

Various synthetic resins such as ABS and PC may be used as the resin for forming the stack plate.

In addition, the leak-preventing guide rings 21, 22, and 23 have elasticity and are made of SEBS (Styrene ethylene butadiene styrene block copolymer) material so that they can function as a packing member that provides sealing force by expansion and contraction.

Meanwhile, in order to improve the moldability of the stack plate structure 10, the runner 140 includes a main transverse runner 141, a first central longitudinal runner 151, a first side longitudinal runner 152, and a first main cross longitudinal runner. It has a structure having a runner 153, a first sub cross longitudinal runner 154, a second side longitudinal runner 162, a second main cross longitudinal runner 163, and a second sub cross longitudinal runner 164.

The main transverse runner 141 is a portion formed to extend from the lower end of the main inlet 131 to cross the space corresponding to the square empty space 14 of the stack plate 12 along the first direction (x).

The first central longitudinal runner 151 extends in both directions from the lower end of the main inlet 131 to the square empty space 14 of the stack plate 12 along the second direction y orthogonal to the first direction and moves downward. This is the part that discharges resin from the extended end.

The first side longitudinal runner 152 extends downward in both directions along the second direction from the first distribution area 141a on the main transverse runner 141 spaced apart to the left with respect to the first central longitudinal runner 151 This is the part that discharges resin from the extended end.

The first main cross longitudinal runner 153 is disposed obliquely with respect to the first side longitudinal runner 152 in the first distribution area 141a and extends crosswise in an X shape to discharge resin from the end extending downward. Part.

The first sub inclined longitudinal runner 154 extends from the first distribution area 141a to an area between the first main crossing longitudinal runner 153 and the first side longitudinal runner 152 toward the first through hole 15. It is a part that discharges resin from the end extending obliquely and extending downward.

The second side longitudinal runner 162 extends in both directions along the second direction from the second distribution area 141b on the main transverse runner 141 spaced to the right with respect to the first central longitudinal runner 151 and extends downward This is the part that discharges resin from the extended end.

The second main cross longitudinal runner 163 is disposed obliquely with respect to the second side longitudinal runner 162 in the second distribution area 141b and extends crosswise in an X shape to discharge resin from the end extending downward. Part.

The second sub inclined longitudinal runner 164 is a space between the second main cross longitudinal runner 163 and the second side longitudinal runner 162 facing the second through hole 16 from the second distribution area 141b. It is a part that discharges resin from the end extending obliquely and extending downward.

In addition, along the direction away from the first central longitudinal runner 151 from the first distribution area 141a of the main transverse runner 141, the separation distance gradually widens around the extension line of the main transverse runner 141, so that mutual branches diverge. A first transverse branch branch runner 155 is formed.

In addition, along the direction away from the first central longitudinal runner 151 from the second distribution area 141b of the main transverse runner 141, the distance is gradually widened by diverging from each other around the extension line of the main transverse runner 141. A second transverse branch runner 155 is formed.

According to the structure of the runner 140, molding errors can be suppressed by efficiently distributing and supplying the resin formed on the stack plates.

According to the dual composite injection mold for manufacturing a stack plate structure of a redox flow battery described above, the leak-preventing guide ring can be integrally molded on the stack plate at once, providing an advantage of improving assembly efficiency.

10: stack plate structure
12: stack plate
14: square empty space
15: first through hole
16: second through hole
21, 22, 23: leak prevention guide ring
110: first mold
120: second mold

Claims (3)

A stack plate having a rectangular square empty space in the center and having first and second through-holes at diagonal corners to support water flow and stack coupling, respectively, and the first and second through-holes of the stack plate and the stack plate. In the double composite injection mold for manufacturing a stack plate structure having a leak-preventing guide ring mounted for leak prevention in a mutually stacked coupled state along a square empty space edge line,
a first mold formed with a first molding groove for supporting injection molding of the stack plate;
The second molding groove is molded with the first mold and forms a cavity for injection molding of the stack plate together with the first molding groove, and the leak-preventing guide ring is inserted and received therein. A double composite injection mold for manufacturing a redox flow battery stack plate structure comprising: a mold. The method of claim 1, further comprising a runner formed at the center of the first mold and distributing and supplying the resin injected from the main inlet extending downward to the cavity,
The runner
a main transverse runner extending from the lower end of the main inlet to cross the square empty space along a first direction;
a first central longitudinal runner extending from the lower end of the main inlet in both directions along the second direction perpendicular to the first direction to the square empty space and discharging resin at the end thereof;
a first side longitudinal runner extending in both directions along the second direction in a first distribution area on the main horizontal runner spaced apart to the left with respect to the first central longitudinal runner and discharging resin at the longitudinal end;
first main cross longitudinal runners disposed obliquely with respect to the first side longitudinal runners in the first distribution area and extending crosswise in an X shape to discharge resin at an end;
a first sub inclined longitudinal runner that obliquely extends from the first distribution area to a region between the first main crossing longitudinal runner and the first side longitudinal runner toward the first through hole;
a second side longitudinal runner extending in both directions along the second direction in a second distribution area on the main horizontal runner spaced apart to the right with respect to the first central longitudinal runner and discharging resin at the longitudinal end;
a second main cross longitudinal runner disposed obliquely with respect to the second side longitudinal runner in the second distribution area, extending to cross in an X shape, and discharging resin at an end thereof;
and a second sub cross longitudinal runner obliquely extending from the second distribution area to an area between the second main cross longitudinal runner and the second side longitudinal runner toward the second through hole. Double composite injection mold for manufacturing DOX flow battery stack plate structure. The double composite injection mold for manufacturing a redox flow battery stack plate structure according to claim 1, wherein the leak-preventing guide ring is formed of SEBS (Styrene ethylene butadiene styrene block copolymer) material.

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