KR20140034975A - Case for secondary battery having locking part - Google Patents

Abstract

A case for a secondary cell given in the present invention includes: a can which includes a lower plate and an upward side wall extended upward from the lower plate and has an internal space with an open top; and a cap which includes an upper plate and a downward side wall extended downward from the upper plate, has an internal space with an open bottom, and separates the internal space of the can from the outside by being inserted into the internal space of the can to make the lower end of the downward side wall be settled on the top surface of the lower plate. The downward side wall includes a combination projection which is extended to the outside and then extended downward. The upward side wall includes a bending unit which is bent to be settled on the top surface of the combination projection. The case for a secondary cell given in the present invention enables combination between the can and the cap without a part protruding to the outside, maintains the combination and sealing between the can and the cap even if internal pressure increases, and improves electrical conductivity with an electrode assembly.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a case for a secondary battery having a locking jaw,

The present invention relates to a case for a secondary battery composed of a can and a cap, more specifically, a can and a cap can be coupled without a portion protruding outward, and the tightening force of the can and the cap and the hermeticity of the inner space can be improved, To a case for a secondary battery capable of improving conductivity with an assembly.

In general, a secondary battery is a battery which can be charged and discharged unlike a primary battery which can not be charged. Recently, a high output secondary battery using a non-aqueous electrolyte having a high energy density has been developed. In the case of a power source for driving a motor, such as an electric car, in which a battery is used for portable electronic devices such as a phone, a notebook computer, and a camcorder, A plurality of secondary batteries are connected in series or in parallel to constitute a large-capacity secondary battery.

The secondary battery is manufactured in various shapes. Typical examples of the secondary battery include a cylindrical battery having an electrode group (or a jelly roll) formed by winding a separator, which is an insulator, between a positive electrode plate and a negative electrode plate, , A stack type in which a plurality of positive electrode plates, negative electrode plates and separator plates are stacked to form an electrode assembly, and then the electrode assembly is embedded in the case.

The case is usually made of a metal plate so as to have a strength higher than a reference value, and comprises a can for inserting the electrolyte solution and the electrode assembly, and a cap for covering the inlet of the can. However, during the use of the lithium ion secondary battery, an increase in the internal pressure due to the generation of gas often causes a leakage of electrolyte at the contact portion between the can and the cap. If the electrolytic solution is leaked in such a manner, it not only has a serious effect on the performance of the battery itself but also seriously contaminates the electronic circuit of the electronic device in which the battery is used to shorten the life of the expensive electronic device do. So that the can and the cap are fully sealed.

Hereinafter, a conventional secondary battery case will be described in detail with reference to the accompanying drawings.

FIG. 1 is an exploded perspective view of a conventional secondary battery case, and FIG. 2 is a cross-sectional view of a conventional secondary battery case.

1, a conventional secondary battery case includes a can 10 having a concave shape with its upper side opened and a flange 12 at an upper side of the can, and an upper inlet of the can 10 and a flange A cap 20 which is seated to cover the flange 12 and which has an edge at its edge to enclose the flange 12 and an electrode assembly 30 which is inserted into the inner space formed by the can 10 and the cap 20 . At this time, the inner space through which the electrode assembly 30 is inserted is filled with the electrolyte, and the gasket 40 is inserted into the portion where the can 10 and the cap 20 abut each other so that the electrolyte does not flow out.

However, in the case of the conventional secondary battery constructed as described above, when the cap 20 is lifted upward as the internal pressure increases, the upper surface of the flange 12 and the lower surface of the cap 20 are opened. There is a disadvantage that the electrolyte and the gas may leak to the outside. Of course, if the length of the flange 12 is increased or the flange 12 wrapped around the edge of the cap 20 is further bent, the above-mentioned leakage of the electrolyte and gas may be reduced, There is a problem in that the overall size of the secondary battery increases, and a separate process is additionally required to bend the flange 12.

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above-described problems, and it is an object of the present invention to provide a can and a cap which can be coupled without a protruding portion, And an object of the present invention is to provide a case for a secondary battery with improved electrical conductivity.

According to an aspect of the present invention, there is provided a secondary battery case, comprising: a lower plate; an upper space defined by the upper side wall extending upward from the lower plate and having an upper space; And a lower end of the lower side wall is inserted into the inner space of the can so that the lower end of the downward side wall is seated on the upper surface of the lower plate, A cap that isolates the space from the outside; Wherein the downward sidewall has a fastening protrusion extending outwardly and extending downwardly and the upward sidewall has a bending portion bent to be seated on an upper surface of the fastening protrusion.

The fastening jaw is formed at the end of the downward sidewall, and the upward sidewall further includes an extension extending upward from the end of the bend and closely contacting the downward sidewall.

The bending portion is formed at the upper end of the upper side wall, and the highest point of the bending portion that is seated on the upper surface of the fastening jaw is set to be equal to or less than the height of the upper surface of the upper plate.

The upper surface of the bending portion is configured to form one plane with the upper surface of the upper plate.

The downward sidewalls are formed in two or more in the vertical direction, and the upward sidewall has two or more bending portions formed in the vertical direction so that different bending portions are seated on the two or more fastening tails.

The bending portion is bent so as to press down the clamping jaw so that the lower end of the downward side wall is pressed onto the lower plate.

The end of the bending portion is located closer to the vertical center of the cap than the inner side of the downward sidewall located below the fastening jaw.

The upper plate includes a depression for depressing the electrode assembly downward when depressed downward and pressed down by bending the upward sidewall.

The sidewall of the depression is formed so as to be inclined in a direction toward the vertical center line of the depression toward the bottom.

And a gasket interposed between the upper side wall and the lower side wall and between the lower side wall and the lower plate to seal between the can and the cap.

The case of the secondary battery according to the present invention has an advantage that the can and the cap can be coupled without a portion protruding to the outside and the connection and sealing between the can and the cap are maintained even if the internal pressure is increased and the conductivity with the electrode assembly is improved have.

1 is an exploded perspective view of a conventional secondary battery case.
2 is a sectional view of a conventional secondary battery case.
3 is an exploded perspective view of a case for a secondary battery according to the present invention.
4 and 5 are sectional views sequentially showing a process of coupling the can with the cap.
6 is a partial cross-sectional view showing a coupling structure of the can and the cap.
7 is a cross-sectional view of a second embodiment of a case for a secondary battery according to the present invention.
8 is a cross-sectional view of a third embodiment of a secondary battery case according to the present invention.
9 is a cross-sectional view of a fourth embodiment of a secondary battery case according to the present invention.

Hereinafter, embodiments of a secondary battery case according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is an exploded perspective view of a case for a secondary battery according to the present invention, FIGS. 4 and 5 are sectional views sequentially showing a process of combining a can and a cap, and FIG. 6 is a partial cross- to be.

In the case of a secondary battery according to the present invention, as in the case of a general secondary battery, the can 100 and the inner space is provided so that the electrode assembly 300 is inserted therein and the electrolyte is filled, and the inner space of the can 100 The cap is sealed by covering the inlet to prevent the electrolyte or the gas generated therefrom from leaking to the outside. The can 100 includes a lower plate 110 serving as a bottom body and an upward side wall 120 extending upward from the lower plate 110 and surrounding lateral sides of the upper space of the lower plate 110, . The cap 200 further includes an upper plate 210 having a size and a shape capable of covering the upper space of the inner space of the can 100 and a lower plate 210 extending downward from the edge of the upper plate 210, And a lower side wall 220 surrounding the lower side wall 220. The inner space is opened to the lower side.

The space surrounded by the downward sidewall 220 is set to be slightly smaller than the space surrounded by the upward sidewall 120 such that the downward sidewall 220 The electrode plate assembly 300 and the electrolytic solution are placed in the inner space of the cap 200. At this time, it is possible to prevent a phenomenon that a gas generated during a chemical reaction between the electrolyte solution filled in the cap 200 and the electrode plate assembly 300 is discharged to the outside through the gap between the downward sidewall 220 and the upward sidewall 120 When the can 100 and the cap 200 are coupled to each other, the outer side surface of the downward side wall 220 is in close contact with the inner side surface of the upward side wall 120.

Meanwhile, the can 100 and the cap 200 constituting the case for the secondary battery are generally made of metal. If two different metals are directly in contact with each other, the two metals can not be closely adhered to each other, The case for the secondary battery according to the present invention can be installed between the upper side wall 120 and the lower side wall 220 and between the lower side wall 220 and the lower plate 110 at a portion where the can 100 contacts the cap 200, A gasket 400 may be further inserted to seal the space between the can 100 and the cap 200.

When the gasket 400 is mounted between the downward sidewall 220 and the upward sidewall 120 so that the downward sidewall 220 and the upward sidewall 120 are overlapped with each other and the internal pressure of the case for the secondary battery increases, The electrolytic solution or the gas does not flow out to the outside between the can 100 and the cap 200. However, when the inner pressure of the case increases, the cap 200 is forced to slide upward, and the can 100 and the cap 200 can be separated from each other. The secondary battery case according to the present invention may solve the above problems, that is, even if an internal pressure is generated so that the cap 200 slides upward and is not separated from the can 100, the upward side wall of the can 100 ( 120) the upper side is bent inward to have a structure that is caught by the cap 200. 1 and 2), when the internal pressure rises, the can 10 and the cap 20 are urged in directions to move away from each other, so that the can 10 and the cap 20 are opened The upper case 210 of the cap 200 is urged in a direction away from the lower case 110 and the lower side wall 220 of the cap 200 is opened to the outside The cap 200 can not be lifted up by the bent portion 122 of the upper side wall 120 and the lower side wall 220 of the cap 200 So that no space is formed between the can 100 and the cap 200 because the upper side wall 120 of the can 100 is pressed. Rather, when the internal pressure is raised, the cap 200 is pressed against the bending portion 122 and the upper side wall 120 with greater force, so that the sealing between the can 100 and the cap 200 is further improved. have.

When the bending portion 122 of the upper side wall 120 is positioned on the upper surface of the cap 210, the bending portion 122 is positioned on the upper surface of the cap 210 So that the secondary battery mounting space must be secured even more. When a large voltage and a large current are required, a plurality of secondary batteries are stacked and electrically connected. When the bending portion 122 protrudes upward from the upper surface of the cap 210, the secondary battery can not be stacked stably, There is a problem that the bending part 122 may be damaged due to an impact on the bending part 122 in the secondary battery stacking process. Therefore, the case for a secondary battery according to the present invention is provided with a lowering sidewall 220 that extends in a direction protruding outward and then extends downward, and the bending portion 122 is provided with a fastening jaw 230 And is configured to be seated on the upper surface of the housing. The bending portion 122 is not in close contact with the upper surface of the upper plate 210 but is in close contact with the fastening protrusion 230 formed in the lower side wall 220, It is possible to stably stack a plurality of secondary batteries and to prevent the bending portion 122 from being damaged.

4, the lower sidewall 220 of the cap 200 is inserted into the inner space of the can 100. At this time, as shown in FIG. 4, The cap 200 is inserted into the can 100 in a fitting manner so as to be in close contact with the inner side surface of the upper side wall 120 of the container 100. Up to this point, the upward side wall 120 of the can 100 maintains a state of being straightly extended toward the upper side. 5, when the cap 200 is completely inserted into the can 100, the upper part of the upper side wall 120 is bent inward and brought into close contact with the upper surface of the tightening jaw 230, Is not caught by the bending portion (122) and does not fall upward. 5, when the clamping jaw 230 is formed at the stop of the downward sidewall 220, the upper plate 210 is lifted upward from the end of the bending portion 122 so that the upper plate 210 is not swayed sideways The extension portion 124 may be provided so as to be in close contact with the downward sidewall 220 (more specifically, the upper end of the downward sidewall 220 above the coupling 230).

1 and 2, when the bending portion 122 of the upward side wall 120 is bent so as to cover the upper surface of the clamping jaw 230, the can 100 and the cap 200 are coupled to each other. The size of the electrode assembly 300 can be kept the same while the size of the product in the width direction can be reduced by the length of the flange 12. If the size of the secondary battery can be reduced as described above, it is possible to reduce the size of various types of electronic products in which the secondary battery is embedded.

The lower end of the downward sidewall 220 may be pressed against the upper surface of the lower plate 110 to prevent electrolyte and gas from leaking out of the case. Accordingly, when the bending portion 122 is bent so as to be stacked on the upper surface of the clamping jaw 230, the bending portion 122 is configured to press downward the downward side wall 220. 4, the bending portion 122 does not merely cover the fastening protrusion 230, but the fastening protrusion 230 is formed in a state in which the fastening protrusion 230 is in the state shown in FIG. The lower end of the downward side wall 220 can be pressed onto the upper surface of the lower plate 110 by sufficiently bending the bending portion 122 until the lower end of the downward side wall 220 is pressed downward. Since the lower end of the downward side wall 220 and the lower plate 110 are also pressed against each other as well as the bending portion 122 and the fastening protrusion 230 are compressed together by bending the bending portion 122, It is possible to more effectively prevent the phenomenon that the gas flows out to the outside. At this time, if the downward side wall 220 located below the clamping jaw 230 is not vertically erected with respect to the lower plate 110 and is inclined upwardly to one side, the bending portion 122 presses the clamping jaw 230 downward The downward sidewalls 220 will fall to one side. The lower side wall 220 positioned below the clamping jaw 230 is disposed at right angles to the lower plate 110 and the bending portion 122 is positioned at the lower side wall 220 in a direction perpendicular to the lower plate 110 It is preferable to constitute such a structure.

When the bending portion 122 is bent and the clamping jaw 230 is pressed downward when the bending portion 122 is short enough to cover the upper surface of the clamping jaw 230, The load is applied only to a part of the bending portion 122 (more specifically, only to a portion located vertically below the bending portion 122), so that the downward side wall 220 may be twisted or deformed. The case for the secondary battery according to the present invention is provided with the bending portion 122 so that the load can be evenly applied to the whole of the downward side wall 220 when the bending portion 122 presses down the fastening protrusion 230. Therefore, The end of the bending portion 122 is positioned closer to the vertical center of the cap 200 than the inner side of the downward sidewall 220 located below the clamping jaw 230. That is, Is preferably designed to extend inward by a distance of at least 'a' from the inner side of the lower side lower wall 220. When the bending part 122 is extended sufficiently long, the load is evenly applied to the entire downward side wall 220 when the bending part 122 presses down the fastening protrusion 230. Thus, the downward side wall 220 Can be prevented from being tilted or twisted to one side.

In this embodiment, only one fastening protrusion 230 is formed on the downward side wall 220 and only one bending portion 122 is formed on the upper side wall 120. However, in the case of the secondary battery according to the present invention, The jaws 230 and the bending portions 122 are arranged in two or more directions in the vertical direction so that at least two jaws 230 and bending portions 122 are formed on the downward side wall 220 and the upward side wall 120, So that the downward sidewall 220 and the upturned sidewall 120 are folded in multiple stages. When the downward sidewall 220 and the upturned sidewall 120 are bent in a multi-stage structure, when the downward sidewall 220 is pressed down by bending the upward sidewall 120, So that it is possible to perform more stable pressurization. At this time, the number of the fastening jaws 230 and the bending portions 122 can be freely changed according to the characteristics of the case for the secondary battery.

When the upper portion of the upper side wall 120 is bent inward (the center direction of the case), when the bent portion is folded, that is, when the corner portions of the neighboring bent portions 122 are overlapped, It may happen that the semiconductor device is not stacked on the semiconductor substrate and is erected. As a result, the folded portion of the bending portion 122 is raised in height, and the function of pressing down the binding jaw 230 can not be normally performed. For example, as shown in the present embodiment, when the fastening jaws 230 are arranged in a quadrangular shape, a bending part 122 is folded into two folds at each corner, so that a phenomenon that the fastening jaws 230 are not laid horizontally occurs. Therefore, in the case of the secondary battery according to the present invention, the bending portion 122 is folded and stacked in the overlapping portion (the edge portion in this embodiment) of the bending portion 122, (The edge portion in this embodiment) of the bending portion 122 is pulled out so that the bending portion 122 is not overlapped at the edge portion.

FIG. 7 is a sectional view of a second embodiment of a secondary battery case according to the present invention, and FIG. 8 is a sectional view of a third embodiment of a secondary battery case according to the present invention.

The case for a secondary battery according to the present invention is configured such that the upper plate 210 is not stably sideways and is stably fixed even if only the bending portion 122 is formed without forming the extended portion 124 on the upper side of the upper side wall 120 . That is, the bending portion 122 is formed at the upper end of the upper side wall 120, and the coupling jaw 230 is lower than the upper plate 210 by a distance which is the sum of the thicknesses of the bending portion 122 and the gasket 400 And the upper surface of the bending portion 122 and the upper surface of the upper plate 210 coincide with each other when the bending portion 122 is seated on the upper surface of the clamping jaw 230. [

If the upper surface of the bending portion 122 and the upper surface of the upper plate 210 are made to coincide with each other such that the upper surface of the bending portion 122 and the upper surface of the upper plate 210 form a single plane, The upper end of the bending portion 122 supports the outer end of the upper plate 210 and thus the upper plate 210 is not swayed in the lateral direction. In addition, when the upper surface of the bending portion 122 and the upper surface of the upper plate 210 form a plane, when the two secondary batteries are stacked one on the other, the upper secondary battery lowers the bending portion 122 of the lower secondary battery to its own weight The inner pressure of the lower secondary battery is increased and the possibility that the bending portion 122 is expanded when the upward external force is applied to the bending portion 122 is reduced. When the upper surface of the bending portion 122 and the upper surface of the upper plate 210 are designed to have the same height, the upper surface of the bending portion 122 is positioned above the upper surface of the upper plate 210 The upper surface of the bending portion 122 may be set to be slightly lower than the upper surface of the upper plate 210.

When two or more coupling tangs 230 and bending portions 122 are formed on the lower sidewall 220 and the upper sidewall 120, 6, the other pair of fastening protrusions 230 and the bending portion 122 are formed at the lower ends of the downward sidewalls 220 and the upper sidewalls 120, as shown in FIG. 7, And may be formed at the upper end of the side wall 220 and the upper side wall 120. When the fastening protrusion 230 and the bending portion 122 are formed as described above, the fastening force between the can 100 and the cap 200 can be more evenly dispersed, and an advantage that a plurality of secondary batteries can be stably stacked have.

7, a separator 330 is interposed between the positive and negative plates 310 and 320. The separator 330 is disposed between the positive and negative plates 310 and 320. The positive electrode plate 310 and the negative electrode plate 320 are alternately stacked, And the positive electrode terminals 312 formed on the respective positive electrode plates 310 are joined to one another to be grounded to the cap 200. The negative electrode terminals 322 formed on each of the negative electrode plates 320 are joined together to form a can 100 As shown in Fig. Accordingly, the cap 200 serves as an anode terminal, and the can 100 acts as a cathode terminal.

The positive electrode terminal 312 is not brought into contact with the cap 200 but the positive electrode 310 located at the uppermost position is in contact with the cap 200. When the positive electrode terminal 312 is in contact with the cap 200, Can be further improved. When the cap 200 is coupled to the can 100, the upper surface of the electrode assembly 300 and the bottom surface of the upper plate 210 are not in contact with each other, and the electrode assembly 300 The lower end of the lower side plate is not brought into contact with the lower plate 110. Therefore, the thickness of the electrode assembly 300 and the length of the lower side plate must be exactly matched to each other. desirable.

The thickness of the electrode assembly 300 and the thickness of the lower side plate are different from each other when the positive electrode plate 310, the negative electrode plate 320 and the separator 330 are overlapped with each other in thickness. There is a difficulty in precisely matching. Therefore, even if a slight error occurs in the thickness of the electrode assembly 300 and the length of the downwardly facing side plate, the case of the secondary battery according to the present invention can prevent the end of the downward side plate from being in close contact with the lower plate 110, A depression 212 may be formed in the top plate 210 at a position corresponding to the electrode assembly 300 so that the top plate 210 can be simultaneously brought into contact with the top plate 210. The depressed portion 212 is formed not by being further coupled to the upper plate 210 but by embossing the upper plate 210. When the upper plate 210 is pressed downward by the bending portion 122, The depression 212 is resiliently deformable to become flat after being contacted with the electrode assembly 300. Accordingly, the upper plate 210 can be further lowered after the depression 212 is brought into contact with the electrode assembly 300, so that the lower end of the lower side wall 220 can be pressed onto the upper surface of the lower plate 110.

Even if the depression 212 is formed in the upper plate 210, the lower end of the lower plate may not be elastically deformed when the cap 200 is made of a thick metal plate. And the upper surface of the electrode assembly 300 is not contacted with the upper plate 210 at the same time. However, the can 100 and the cap 200 constituting the case for the secondary battery are generally made of a thin metal plate, so that they can be elastically deformed and restored when they are embossed so as to protrude to one side as shown in FIG.

When the side wall of the depression 212 is vertically raised, the depression 212 may be difficult to be deformed when the upper plate 210 is pressed downward. Therefore, the side wall of the depression 212 is formed to be inclined Do. Of course, even when the side wall of the depression 212 is formed so as to be inclined toward the direction away from the vertical center line of the depression 212 as it goes down, that is, toward the lower side, the depression 212 can be easily deformed elastically However, in such a case, the depressed portion 212 can not be machined by a simple punching process. Therefore, it is preferable that the depressed portion 212 is formed to be inclined in a direction approaching the vertical center line of the depressed portion 212 as it goes downward as shown in this embodiment.

9 is a cross-sectional view of a fourth embodiment of a secondary battery case according to the present invention.

3 to 8, the case for the secondary battery according to the present invention has a rectangular shape. However, the case for the secondary battery according to the present invention may have a circular shape as shown in FIG. 10, It can also be made in button shape. When the case for a secondary battery according to the present invention is manufactured in the form of a coin or a button, the fastening force between the can and the cap and the airtightness of the inner space can be secured in all areas. It is preferably applied to a lithium ion secondary battery such as a button type battery. Of course, the case for a secondary battery according to the present invention is not limited to a lithium ion secondary battery such as a coin type and a button type, and can be applied to a secondary battery of various shapes.

In the case where the case for a secondary battery according to the present invention is manufactured in a coin or button shape as in the present embodiment, a fastening protrusion 230 is formed on the downward side wall 220, The portion 122 may be seated on the clamping jaw 230 to press down the clamping jaw 230. [ Even when the can 100 and the cap 200 are formed in a coin shape or a button shape, since the bending portion 122 is seated on the fastening protrusion 230, And the effect that can be obtained by this structure are substantially the same as those of the embodiment shown in FIGS. 3 to 8, and thus a detailed description thereof will be omitted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited to the disclosed exemplary embodiments. It will also be appreciated that many modifications and variations will be apparent to those skilled in the art without departing from the scope of the present invention.

100: can 110: bottom plate
120: upper side wall 122:
122: bending portion 124: extension portion
200: cap 210: top plate
212: depression 220: downward side wall
230: fastening jaw 300: electrode assembly
310: Positive electrode plate 312: Positive electrode terminal
320: cathode plate 322: cathode terminal
330: separator 400: gasket

Claims (10)

A can comprising a lower plate and an upper side wall extending upward from the lower plate and having an upper space opened;
And a lower end of the lower side wall is inserted into the inner space of the can so that the lower end of the downward side wall is seated on the upper surface of the lower plate, A cap that isolates the space from the outside;
Including, The downward side wall has a fastening jaw extending to the outside again downward downward, The upper side wall is a secondary battery case characterized in that it comprises a bending portion to be seated on the upper surface of the fastening jaw.
The method of claim 1,
The fastening jaws being formed in the interruption of the downward sidewalls,
The upward side wall, the secondary battery case further comprises an extension extending in close contact with the downward side wall while extending from the end of the bending portion.
The method of claim 1,
The bending part is formed at an upper end of the upward side wall, the height of the highest point of the bending part seated on the upper surface of the fastening jaw, the secondary battery case, characterized in that less than the height of the upper surface of the upper plate.
The method of claim 3,
And the upper surface of the bending portion forms one plane with the upper surface of the upper plate.
5. The method according to any one of claims 1 to 4,
Wherein the downward sidewalls are formed in two or more in the vertical direction and the upward sidewalls are formed in two or more in the vertical direction of the bending portion,
And a plurality of bending portions are seated on the two or more fastening jaws, respectively.
5. The method according to any one of claims 1 to 4,
Wherein the bending portion is bent so as to press down the engaging jaw so that a lower end of the downward side wall is pressed onto the lower plate.
5. The method according to any one of claims 1 to 4,
Wherein an end of the bending portion is located closer to a vertical center of the cap than an inner side surface of a downward side wall positioned below the fastening jaw.
5. The method according to any one of claims 1 to 4,
The upper plate is a case for a secondary battery, characterized in that provided with a depression for pressing down the electrode assembly when pressed downward by the bending of the upward side wall recessed downward.
9. The method of claim 8,
Wherein the side wall of the depression is formed to be inclined in a direction toward the vertical center line of the depression toward the bottom.
5. The method according to any one of claims 1 to 4,
Further comprising a gasket interposed between the upper side wall and the lower side wall and between the lower side wall and the lower plate to seal between the can and the cap.

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