KR20120118882A - Stacking system and method for secondary battery - Google Patents

Abstract

PURPOSE: A device and method for laminating cell stacks inside a secondary battery is provided to maximize productivity of a secondary battery to remarkably reduce production cost of a secondary battery, and to maximize productivity. CONSTITUTION: A method for laminating cell stacks inside a secondary battery comprises: a step of attaching each reel type separator(400) on both sides of a first electrode plate(200) to continuously supply the first electrode plate and the separator; and a step of alternately inserting a second electrode plate(300) to be vertical to the first electrode plate separated from both sides of the first electrode plate with a constant distance. The first electrode plate and the separator are folded to a zigzag shape.

Description

Stacking system and method for secondary battery internal cell stack {Stacking system and method for Secondary Battery}

The present invention relates to an apparatus and a method for stacking a secondary cell internal cell stack, and more particularly, a first electrode plate which is either a negative electrode plate or a positive electrode plate, a second electrode plate having a polarity opposite to that of the first electrode plate, and In the manufacture of a secondary battery inner cell stack including a separator disposed between the first electrode plate and the second electrode plate, the separator of the reel type adheres to both sides of the first electrode plate so that the first electrode plate is in close contact with each other. And after the separator is continuously supplied in a single shape, the second electrode plates are alternately inserted to be perpendicular to the first electrode plate at regular intervals from both sides of the first electrode plate, and are sequentially inserted in opposite directions. The present invention relates to a secondary battery internal cell stack stacking apparatus and method for folding an electrode plate and a separator in a zigzag form.

Unlike primary batteries, rechargeable batteries that can be charged and discharged are being actively researched due to the development of high-tech fields such as digital cameras, cellular phones, notebook computers, and hybrid cars. Secondary batteries include nickel-cadmium batteries, nickel-metal hydride batteries, nickel-hydrogen batteries, lithium secondary batteries, and the like. FIG. 1 illustrates a model of a principle of operation of a lithium battery, which is one of such secondary batteries. As shown in FIG. 1, the secondary battery is formed by sequentially stacking a positive electrode plate, a separator, and a negative electrode plate in an electrolyte solution.

Such a method of manufacturing a secondary cell inner cell stack is largely divided into two ways. In the case of a small secondary battery, a method of arranging a negative electrode plate and a positive electrode plate on a separator and rolling them into a jelly-roll form is often used. In the case of a medium and large secondary battery having more electric capacity, A lot of methods are used for stacking a cathode plate, a cathode plate, and a separator in an appropriate order.

There are a number of ways to fabricate the inner cell stack of the secondary battery in a stacked manner, of which Z-folding (also called Z-folding, zigzag folding or accordion folding) method as shown in FIG. ) To form a zigzag folded form and the negative plate (1) and the positive electrode plate (2) are alternately stacked between them inserted. A secondary battery inner cell stack having a Z-folded stack is disclosed in various prior arts, such as Korean Patent No. 0313119 and US Patent Application No. 2005/0048361.

In order to actually implement the Z-folding stacked form, prior art such as Korean Patent No. 0009604 discloses a method of folding a plurality of negative electrode plates on one side of the separator in an unfolded state and a plurality of negative electrode plates on the other side thereof, and then folding it. have. This method is also widely used to fabricate a jelly-roll type secondary battery internal cell stack. However, this method is difficult to align the negative electrode plate and the positive electrode plate, and recently, in the fabrication of Z-folding stacked secondary battery internal cell stack device as shown in Figures 3 and 4 Is conventionally used.

In the manner shown in FIG. 3, the negative electrode plate 1 and the positive electrode plate 2 are stacked on separate tables spaced from side to side, and the separator feeder and the Z-folding laminating apparatus 10 'are moved together by a predetermined distance from side to side. The separator 3 is folded in a zigzag form, and the following process is repeated. First, when the entire apparatus is moved to the left side (based on FIG. 3), the Z-folding lamination apparatus 10 ′ on the left side adsorbs the negative electrode plate 1, and then moves to the right to move the Z-folding lamination apparatus 10 on the left side. When the ') is in the center, the left Z-folding lamination apparatus 10' is disposed by placing the negative electrode plate 1 on the separator 3. At the same time, the Z-folding lamination apparatus 10 'on the right side adsorbs the positive electrode plate 2. After moving to the left again and the right Z-folding lamination device 10 'is in the center, the right Z-folding lamination device 10' is disposed by placing the positive electrode plate 2 on the separator 3. . Of course, at the same time, the left Z-folding lamination apparatus 10 ′ is allowed to adsorb the negative electrode plate 1, and as the process is repeated, the separator 3 is folded in a zigzag form, and between the above, The negative electrode plate 1 and the positive electrode plate 2 are stacked in an alternately inserted form.

In the manner shown in Fig. 4, the separator feeder is fixed while the table on which the stack is placed and the Z-folding lamination apparatus 10 "are moved from side to side, respectively. It operates in a manner similar to the Z-folding lamination apparatus 10 'of the illustrated manner, and thus the detailed description is omitted.

By the way, such a conventional method can obtain a good result with respect to the alignment state, but because it is stacked by one layer, it takes a very long time to complete a single cell stack, thereby reducing the productivity significantly There is this. Therefore, there has been a constant demand among those skilled in the art to improve this problem.

The present invention has been made to solve the problems of the prior art as described above, an object of the present invention is a first electrode plate of any one of a negative electrode plate or a positive electrode plate, and a second electrode having a polarity opposite to the first electrode plate In the manufacture of a secondary battery inner cell stack including a plate and a separator disposed between the first electrode plate and the second electrode plate, the separators of the reel type are in close contact with both sides of the first electrode plate. After the first electrode plate and the separator are continuously supplied in the form of a single letter, the second electrode plate is alternately inserted to be perpendicular to the first electrode plate at regular intervals from both sides of the first electrode plate, and sequentially in opposite directions. The present invention provides a secondary battery internal cell stack stacking apparatus and method for inserting the first electrode plate and the separator to be folded in a zigzag form.

The secondary battery inner cell stack stacking apparatus of the present invention includes a first electrode plate 200 which is either a negative electrode plate or a positive electrode plate, a second electrode plate 300 having a polarity opposite to that of the first electrode plate 200, and Secondary battery inner cell stack stacking apparatus 10 for manufacturing a secondary battery inner cell stack 100 including a separator 400 disposed between the first electrode plate 200 and the second electrode plate 300. ), The reel-type separation membranes 400 are in close contact with both sides of the first electrode plate 200, and the first electrode plate 200 and the separation membrane 400 are continuously supplied in a single letter shape. The second electrode plate 300 is alternately inserted so as to be perpendicular to the first electrode plate 200 at regular intervals from both sides of the first electrode plate 200, and on both sides of the first electrode plate 200. The supplied second electrode plate 300 is sequentially inserted in opposite directions to fold the first electrode plate 200 and the separator 400 in a zigzag form. .

In addition, the second electrode plate 300 is characterized in that the negative electrode or the positive electrode plate is a mono-cell (mono-cell) formed by cutting to a predetermined size.

In addition, the first electrode plate 200 may be supplied in a reel type to be in close contact with the separator 400.

In addition, the first electrode plate 200 is a mono-cell formed by cutting a negative electrode plate or a positive electrode plate to a predetermined size, and is aligned side by side in the supply direction of the separator 400 to be laminated with the separator 400. It is characterized by being laminated by.

In addition, the secondary battery inner cell stack 100 is characterized in that the negative electrode plate is located on the uppermost layer and the lowermost layer forming each outer surface.

In addition, the secondary battery inner cell stack 100 may be positioned at opposite sides of each tab 210 of the first electrode plate 200 and each tab 310 of the second electrode plate 300. It is characterized in that the arrangement.

In addition, the secondary battery inner cell stack 100 is disposed such that each tab 210 of the first electrode plate 200 and each tab 310 of the second electrode plate 300 are positioned on the same side of each other. It is characterized by.

In addition, in the secondary battery inner cell stack stacking apparatus 10, the separator feeder 500 is disposed to supply the separator 400 to both sides of the first electrode plate 200 at an initial position. On both sides of the first electrode plate 200, the pressing roll 600 is provided on both sides of the first electrode plate 200 in which the separator 400 is in close contact with each other so that the separator 400 is in close contact with each other. The second electrode plate 300 is disposed to be alternately supplied to both sides in a direction perpendicular to the first electrode plate 200 adjacent to an end portion in the advancing direction of the first electrode plate 200. The second electrode plate feeder 700 is disposed on both sides of the first electrode plate 200.

In addition, in the secondary battery internal cell stack stacking method using the secondary battery internal cell stack stacking device 10, a) the first electrode plate (1) in the advancing direction of the secondary battery internal cell stack stacking device 10; 200) being supplied; b) the separator 400 is supplied from both sides of the first electrode plate 200 by the separator supplier 500; c) the first electrode plate 200 and the separator 400 are moved in the advancing direction along the pressing roll 600 and closely contacted with each other; d) the second electrode plate 300 is alternated with each other by the second electrode plate feeder 700 at both sides in a direction perpendicular to the first electrode plate 200 in which the separator 400 is in close contact with both sides. Fed step; e) the second electrode plate 300 is alternately inserted into each other and sequentially inserted in the opposite direction to fold the first electrode plate 200 and the separator 400 in a zigzag form; And a control unit.

In the secondary battery internal cell stack stacking apparatus and method of the present invention, the reel-type separators are in close contact with both sides of the first electrode plate, which is either a negative electrode plate or a positive electrode plate, so that the first electrode plate and the separator are continuous in a single shape. After being supplied, second electrode plates having different polarities from the first electrode plate are alternately inserted to be perpendicular to the first electrode plate at regular intervals from both sides of the first electrode plate, and are sequentially inserted in opposite directions to each other. 1 The electrode plate and the separator are folded in a zigzag form, thereby solving the problem of the Z-folding stacking method, which has a long time required to complete the cell stack by stacking the separator, the cathode plate and the anode plate separately one by one. The advantage is that the production time can be shortened.

In addition, the secondary battery internal cell stack stacking apparatus and method of the present invention can maximize the productivity of the secondary battery, and thus, there is an advantage in that the production cost can be maximized by greatly reducing the secondary battery production cost.

1 is an operating model of a typical secondary battery.
2 is a view illustrating a secondary battery inner cell stack manufactured by Z-folding lamination.
3 and 4 is a view showing a conventional Z-folding stacking method.
5 is a schematic view of a secondary battery internal cell stack stacking device according to the present invention;
6 is a view showing a close relationship between the separator and the first electrode plate in FIG.
FIG. 7 is a cross-sectional view of a secondary battery inner cell stack manufactured by the secondary battery inner cell stack stacking apparatus of FIG. 5. FIG.
8 is a schematic view of another secondary battery internal cell stack stacking device according to the present invention;
9 is a view showing a close relationship between the separator and the first electrode plate in FIG.
FIG. 10 is a cross-sectional view of a secondary battery inner cell stack manufactured by the secondary battery inner cell stack stacking apparatus of FIG. 8. FIG.
11 is a schematic view of another secondary battery internal cell stack stacking device according to the present invention.
12 is a perspective view of a secondary battery inner cell stack manufactured by the secondary battery inner cell stack stacking device of any one of FIGS. 5, 8, and 11;
FIG. 13 is a perspective view of another secondary battery inner cell stack manufactured by the secondary battery inner cell stack stacking device of any one of FIGS. 5, 8, and 11.

Hereinafter, a secondary battery internal cell stack stacking apparatus and method according to the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

5 is a schematic view of a secondary battery inner cell stack stacking apparatus according to the present invention, FIG. 6 is a view showing a close relationship between a separator and a first electrode plate in FIG. 5, and FIG. 7 is a secondary cell inner cell of FIG. 5. FIG. 8 is a cross-sectional view of a secondary battery inner cell stack manufactured through the stack stacking apparatus. FIG. 8 is a schematic view of another secondary battery inner cell stack stacking apparatus according to the present invention. FIG. 9 is a separator and a first electrode plate in FIG. 8. 10 is a cross-sectional view of a secondary battery inner cell stack manufactured by the secondary battery inner cell stack stacking apparatus of FIG. 8, and FIG. 11 is another secondary battery inner cell according to the present invention. 12 is a schematic view of a stack stacking apparatus, FIG. 12 is a perspective view of a secondary battery inner cell stack manufactured through the secondary battery inner cell stack stacking apparatus of any one of FIGS. 5, 8, and 11, and FIG. Secondary battery internal cell stack stacking device of any one of 11 A perspective view of the another secondary cell inside the cell stack prepared by.

The secondary battery inner cell stack stacking apparatus 10 of the present invention includes a first electrode plate 200 which is either a negative electrode plate or a positive electrode plate, and a second electrode plate 300 having a polarity opposite to that of the first electrode plate 200. ), And a separator 400 disposed between the first electrode plate 200 and the second electrode plate 300.

In particular, in the secondary battery inner cell stack stacking apparatus 10, the reel type separator 400 is in close contact with both sides of the first electrode plate 200, so that the first electrode plate 200 and the separator 400 are in close contact with each other. ) Is continuously supplied in the form of one letter, and the second electrode plate 300 is alternately inserted to be perpendicular to the first electrode plate 200 at regular intervals from both sides of the first electrode plate 200. The second electrode plate 300 supplied from both sides of the first electrode plate 200 are sequentially inserted in opposite directions so that the first electrode plate 200 and the separator 400 are folded in a zigzag form. do.

In this case, the second electrode plate 300 may be a mono-cell formed by cutting a negative electrode plate or a positive electrode plate to a predetermined size.

An exemplary embodiment of the secondary battery inner cell stack stacking apparatus 10 according to the present invention is briefly illustrated in FIG. 5.

First, the configuration of the secondary battery internal cell stack stacking apparatus 10 according to the present invention will be briefly described with reference to FIG. 5.

In the secondary battery internal cell stack stacking apparatus 10, the separator feeder 500 is disposed to supply the separator 400 to both sides of the first electrode plate 200 at an initial position. A plurality of compression rolls 600 are disposed on both sides of the first electrode plate 200 in which the separator 400 is in close contact with each other so that the separator 400 is in close contact with the both sides of the first electrode plate 200. And a second electrode such that the second electrode plate 300 is alternately supplied to both sides in a direction perpendicular to the first electrode plate 200 adjacent to an end portion in the advancing direction of the first electrode plate 200. The plate feeder 700 may be disposed on both sides of the first electrode plate 200.

The pressing roll 600 is installed facing each other on both sides of the first electrode plate 200 so as to compress and transport the separator 400 and the first electrode plate 200, spaced apart a certain distance in the advancing direction It is preferable to provide a plurality.

5 illustrates a case where the first electrode plate 200 is a negative electrode plate and is a mono-cell formed by cutting to a predetermined size.

In this case, as shown in FIG. 6, the negative electrode plates may be arranged side by side in the supply direction of the separator 400 to be stacked by lamination with the separator 400.

In this case, the electrode tabs of the negative electrode plate are preferably formed to be aligned side by side in one direction, and the electrode tabs of the positive electrode plates which are alternately inserted from both sides in the vertical direction to the negative electrode plate are on the side opposite to the electrode tabs of the negative electrode plate. It may be arranged to be positioned, or may be arranged to be located on the same side of each other.

The cross section in the vertical direction of the secondary battery inner cell stack 100 manufactured by the secondary battery inner cell stack stacking apparatus 10 of FIG. 5 is the same as that of FIG. 7.

As shown in FIG. 7, in the secondary battery inner cell stack 100, a separator 400 adhered to both sides of the negative electrode plate is positioned between the negative electrode plate and the positive electrode plate, and the positive electrode plate is based on the separator 400. The negative electrode plates are alternately stacked.

8 is a view showing another embodiment of a secondary battery internal cell stack stacking apparatus 10 according to the present invention.

The secondary battery inner cell stack stacking apparatus 10 of FIG. 8 illustrates a case in which the first electrode plate 200 is a negative electrode plate, and the negative electrode plate is supplied in a reel-type that is not cut to be in close contact with the separator 400. to be.

In this case, as shown in FIG. 9, the negative electrode plates may be arranged side by side in the supply direction of the separator 400 to be stacked by lamination with the separator 400.

In this case, the electrode tabs of the negative electrode plate are preferably formed to be aligned side by side in one direction, and the electrode tabs of the positive electrode plates which are alternately inserted from both sides in the vertical direction to the negative electrode plate are on the side opposite to the electrode tabs of the negative electrode plate. It may be arranged to be positioned, or may be arranged to be located on the same side of each other.

The cross section in the vertical direction of the secondary battery inner cell stack 100 manufactured by the secondary battery inner cell stack stacking apparatus 10 of FIG. 8 is the same as that of FIG. 10.

As shown in FIG. 10, in the secondary battery inner cell stack 100, a separator 400 adhered to both sides of the negative electrode plate is positioned between the negative electrode plate and the positive electrode plate, and the positive electrode plate based on the separator 400. The negative electrode plates are alternately stacked.

11 is a view showing another embodiment of a secondary battery internal cell stack stacking apparatus 10 according to the present invention.

11 illustrates a case in which the first electrode plate 200 is a positive electrode plate, and the positive electrode plate is a mono-cell formed by cutting to a predetermined size.

In the secondary battery internal cell stack stacking apparatus 10, polarities of the secondary battery internal cell stack stacking apparatus 10, the first electrode plate 200, and the second electrode plate 300 illustrated in FIG. 5 are opposite to each other. It will be shown when.

Therefore, similar to the negative electrode plate of FIG. 5, the positive electrode plates may be aligned side by side in the supply direction of the separator 400 to be stacked by lamination with the separator 400.

In this case, the positive electrode plate may be a polymer film coating on the electrode surface.

On the other hand, when the secondary battery inner cell stack 100 is stacked in a positive electrode / cathode facing structure, the negative electrode occupies as much area as possible, for example, when used in a lithium secondary battery, lithium metal during charge and discharge The phenomenon of dendrite growth in the cathode and the like can be suppressed as much as possible.

Accordingly, the secondary battery inner cell stack 100 may be provided with a negative electrode plate on the uppermost layer and the lowermost layer forming each outer surface thereof.

In the secondary battery inner cell stack stacking apparatus 10 illustrated in FIGS. 5, 8, and 11, the second electrode plate feeder 700 is positioned at both sides of the first electrode plate 200 in close contact with the separator 400. In this case, a plurality of cells may be installed to be spaced apart from each other by a predetermined distance, and the second electrode plates 300 may be installed at a distance less than twice the cell stack size so that the second electrode plates 300 may be alternately inserted in the opposite direction and folded.

Also. The separator feeder 500 may be installed to provide a smooth and smooth supply by applying a proper tension to the separator 400.

Meanwhile, the secondary battery inner cell stack stacking method using the secondary battery inner cell stack stacking device 10 as described above is as follows.

First, the first electrode plate 200 is supplied in the advancing direction of the secondary battery inner cell stack stacking device 10, and the separator is fed from both sides of the first electrode plate 200 by the separator supplier 500. 400 is supplied.

Next, the first electrode plate 200 and the separator 400 are transferred along the pressing roll 600 in the advancing direction, and the first electrode plate 200 is moved by the pressing roll 600 while being transferred. And the separator 400 is in close contact with each other.

In this case, the first electrode plate 200 may be aligned and side by side in the supply direction of the separator 400 to be bonded and laminated by the separator 400.

In this case, in the secondary battery inner cell stack 100, the first electrode plate 200 is bonded to the separator 400 by lamination, so that the positional variation of the electrode is small, thereby maintaining a more stable shape.

Subsequently, the secondary battery inner cell stack stacking apparatus 10 may supply the second electrode plate feeder 700 at both sides in a direction perpendicular to the first electrode plate 200 having the separator 400 adhered to both sides thereof. The second electrode plate 300 is alternately supplied to each other by the second electrode plate 300, and the second electrode plate 300 is alternately inserted into each other and sequentially inserted into the first electrode plate 200 in the opposite direction. The 200 and the separator 400 are folded in a zigzag form, and the secondary battery inner cell stack 100 is formed.

Accordingly, in the secondary battery internal cell stack stacking apparatus and method of the present invention, after the first electrode plate and the separator are continuously supplied in the form of one letter, the second electrode plate having a different polarity from the first electrode plate is the first electrode plate. The electrode plates are alternately inserted to be perpendicular to the first electrode plate at regular intervals, and are sequentially inserted in opposite directions so that the first electrode plate and the separator are folded in a zigzag form. In order to solve the problem of the Z-folding lamination method, which took a long time to complete the cell stack by stacking the layers separately, and to speed up, there is an advantage that the production time can be significantly reduced.

In addition, the secondary battery internal cell stack stacking apparatus and method of the present invention can maximize the productivity of the secondary battery, and thus, there is an advantage in that the production cost can be maximized by greatly reducing the secondary battery production cost.

10: secondary battery internal cell stack device
100: secondary battery internal cell stack
200: first electrode plate
210: tab of the first electrode plate
300: second electrode plate
310: tab of the second electrode plate
400: separator
500 Membrane Feeder
600: pressing roll
700: second electrode plate feeder

Claims (9)

The first electrode plate 200 which is either a negative electrode plate or a positive electrode plate, the second electrode plate 300 having a polarity opposite to the first electrode plate 200, the first electrode plate 200 and the second electrode In the secondary battery internal cell stack stacking apparatus 10 for manufacturing a secondary battery internal cell stack 100 including a separator 400 disposed between the plates 300,
The reel-type separator 400 is in close contact with both sides of the first electrode plate 200 so that the first electrode plate 200 and the separator 400 are continuously supplied in a single shape, and then the second electrode The plates 300 are alternately inserted to be perpendicular to the first electrode plate 200 at regular intervals from both sides of the first electrode plate 200.
The second electrode plate 300 supplied from both sides of the first electrode plate 200 are sequentially inserted in opposite directions so that the first electrode plate 200 and the separator 400 are folded in a zigzag form. Secondary battery internal cell stack stacking device.
The method of claim 1,
The second electrode plate 300 is
The secondary battery internal cell stack stacking apparatus, characterized in that the negative electrode or the positive electrode plate is a mono-cell (mono-cell) formed by cutting to a predetermined size.
The method of claim 2,
The first electrode plate 200
The secondary battery inner cell stack stacking apparatus is supplied in a reel type and in close contact with the separator 400.
The method of claim 2.
The first electrode plate 200
The negative electrode or the positive electrode plate is a mono-cell (mono-cell) formed by cutting to a predetermined size, the secondary battery characterized in that the side by side aligned in the supply direction of the separator 400 is laminated by the separator 400 and lamination Internal cell stack stacking device.
The method according to any one of claims 1 to 4,
The secondary battery inner cell stack 100 is
A secondary battery inner cell stack stacking apparatus, characterized in that a negative electrode plate is positioned on the uppermost layer and the lowermost layer forming each outer surface.
The method according to any one of claims 1 to 4,
The secondary battery inner cell stack 100 is
Each of the tabs 210 of the first electrode plate 200 and each of the tabs 310 of the second electrode plate 300 are disposed so as to be positioned on opposite sides of each other. Device.
The method according to any one of claims 1 to 4,
The secondary battery inner cell stack 100 is
Each tab 210 of the first electrode plate 200 and each tab 310 of the second electrode plate 300 is disposed so as to be located on the same side of each other, the secondary battery internal cell stack stacking device .
The method according to any one of claims 1 to 4,
The secondary battery internal cell stack stacking apparatus 10 is
The separator feeder 500 is disposed to supply the separator 400 to both sides of the first electrode plate 200 at an initial position.
A plurality of compression rolls 600 are provided on both sides of the first electrode plate 200 in which the separator 400 is in close contact with each other so that the separator 400 is in close contact with the both sides of the first electrode plate 200. Will be placed,
A second electrode plate feeder such that the second electrode plate 300 is alternately supplied to both sides in a direction perpendicular to the first electrode plate 200 adjacent to an end portion in the advancing direction of the first electrode plate 200. Secondary battery internal cell stack stacking device characterized in that 700 is disposed on both sides of the first electrode plate (200).
In the secondary battery internal cell stack stacking method using the secondary battery internal cell stack stacking apparatus 10 according to claim 8,
a) supplying the first electrode plate 200 in the advancing direction of the secondary battery inner cell stack stacking device 10;
b) the separator 400 is supplied from both sides of the first electrode plate 200 by the separator supplier 500;
c) the first electrode plate 200 and the separator 400 are moved in the advancing direction along the pressing roll 600 and closely contacted with each other;
d) the second electrode plate 300 is alternated with each other by the second electrode plate feeder 700 at both sides in a direction perpendicular to the first electrode plate 200 in which the separator 400 is in close contact with both sides. Fed step;
e) the second electrode plate 300 is alternately inserted into each other and sequentially inserted in the opposite direction to fold the first electrode plate 200 and the separator 400 in a zigzag form; Secondary battery inner cell stack stacking method comprising a.

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