KR100274939B1 - A device for sealing the electrode terminals of lithium batterys - Google Patents

Abstract

The present invention relates to an electrode terminal sealing device of a lithium battery, the technical spirit of the upper and lower gaskets 230a and 230b to insulate the upper cap 220, which is a negative electrode terminal, and the rivet 210, which is a positive electrode terminal. When the compression combination of the rivet 210 and the upper cap 220. Upper and lower gaskets 230 of the lithium battery 200 are installed by installing the first and second sealing members 240a and 240b on the sealing portions 220a and 210a of the upper cap 220 and the rivet 210, respectively. ) And the sealing state between the rivet 210 and the upper cap 220 is characterized by closeness.

Accordingly, the sealing state of the electrode terminals of the lithium battery is kept extremely good, the external leakage of the internal electrolyte is effectively blocked, and the product reliability of the lithium battery is improved.

Description

Electrode terminal sealing device of lithium battery

The present invention relates to a lithium battery having a high energy, in particular, a lithium ion secondary battery, in which the positive electrode and negative electrode terminals of the rivet and the upper cap are sealed to the electrode terminal sealing apparatus of the lithium battery to be more closely sealed. In more detail, the first and second seals are installed on the upper cap and the rivet, respectively, when the upper cap and the negative terminal are insulated from each other, and the upper cap and the lavet and the gasket are crimped together. By means of the member, the sealing state between the gasket and each electrode terminal is more closely maintained, as well as preventing the external leakage of the internal electrolyte, thereby improving the product reliability of the lithium battery. will be.

In general, a lithium battery, in particular, a lithium ion secondary battery, is an intercalation reaction of lithium ions in which the charging reaction of the negative electrode is relatively fast, and can be rapidly charged and is a high voltage battery having safety because it exists in a lithium ion state. The use and research is increasing rapidly, and such lithium batteries are divided into cylindrical or rectangular lithium batteries according to their shape.

In the structure of the conventional rectangular lithium battery related to such a technique, as shown in FIG. 1, the anode lead 11 and the spacer of the positive electrode plate 10 wound around the inner center of the case 2 of the lithium battery 1 are illustrated. The upper cap 40 coupled to the upper side of the case 2 to which the rivet 30 connected and connected through the 12 and the negative electrode lead 21 of the negative electrode plate 20 wound to the outside of the positive electrode plate 10 are connected. ) Is made of a structure in which the upper and lower gaskets 50a and 50b are integrally compressed with the rivet 30 in an insulated state.

In the electrode terminal sealing structure of the conventional rectangular lithium battery having the structure as described above, after the electrolyte is injected through the electrolyte inlet 40a of the upper cap 40, and then weld-sealed as a fixed ball (40b), The electrolyte solution is the upper and lower gaskets (50a, 50b) that are crimped together with the rivet 30 to prevent external leakage, and also the rivet 30, the positive terminal, and the upper cap 40, the negative terminal, are also the gasket. It is to be insulated as (50).

However, in the electrode terminal sealing structure of the conventional rectangular lithium battery as described above, the upper and lower gaskets 50a and 50b and the inner upper cap 12 are integrally crimped together as a rivet 30 which is a positive electrode terminal. Due to the structure being sealed or the structure in which the upper and lower gaskets 50a and 50b and the upper cap 40 are simply pressed and fixed on the plane, the pressing force may be maintained in the longitudinal direction, but separately in the horizontal direction. When no external shock is applied to the lithium battery 1 because there is no fixing means, fine spacing is easily generated between the contact surfaces of the upper and lower gaskets 50a and 50b and the upper cap 40 and the rivet 30. Accordingly, there is a disadvantage in that the electrolyte, which is filled in the battery 1 and is subjected to a constant pressure, easily leaks to the outside.

In addition, when the electrolyte leaks, a fire occurs due to a short between the electrode terminals 12 and 30, or the leaked electrolyte damages the components of the device using the battery 1, and the electrode terminal sealing structure of the lithium battery is weak. As a result, there were problems such as extremely low product reliability of the lithium battery 1.

On the other hand, in the conventional electrode terminal sealing structure for improving the sealing structure by the flat gasket as described above, and the electrode terminal sealing structure known by Japanese Patent Application Laid-open No. Hei 9-171809, (a) of FIG. As shown in (b), the gaskets 130 and 130 ', which are not planar and bent on the outer circumferential surface of the rivet 110 or the hollow cap 110', have the upper cap 120 (the lower side) ( 120 ') is made of a structure that is integrally press-bonded.

In the electrode terminal sealing structure of another conventional lithium battery 100, 100 'having such a structure, one gasket 130, 130' instead of two gaskets on a plane, the upper cap 120 The rivet 110 or the hollow cap 110 'is integrally coupled with the 120 to prevent leakage of the internal electrolyte, and the upper caps 120 and 120' and the rivet 110, respectively, are electrode terminals. Or it is to maintain the insulation state of the hollow cap (110 ').

However, in the electrode terminal sealing structure of the conventional lithium battery as described above, as one bent gasket (110, 110 ') to maintain the sealing state in the longitudinal and transverse directions, as shown in FIG. While the manufacturing of the bent gasket 110 and 110 ′ is more difficult than the gasket 50 formed in a planar shape, the assembly work with the rivet 110 or the hollow cap 110 ′ is complicated. There have been problems such as decreased manufacturing productivity of the batteries 100, 100 '.

The present invention has been made in order to improve the various problems as described above, and its purpose is to insulate the upper cap and the positive terminal of the negative terminal and the rivet, the upper cap and rivet and to prevent leakage of the internal electrolyte and When the gasket is crimped and coupled, the first and second sealing members respectively installed on the upper cap and the rivet maintain the sealing state between the gasket and each electrode terminal more closely, and prevent external leakage of the internal electrolyte. Product reliability is improved by preventing damage to the equipment used in lithium batteries, and in particular, the simple structure that press-fits the flat gasket with the first and second sealing members of the upper cap and rivet is easy to manufacture and install. An electrode terminal sealing apparatus of a lithium battery is provided.

1 is a cross-sectional view showing an electrode terminal sealing structure of a conventional rectangular lithium battery

2 (a) and 2 (b) are cross-sectional views illustrating main parts of an electrode terminal sealing structure of another conventional lithium battery.

3 is a cross-sectional view showing a first embodiment of an electrode terminal sealing apparatus of a lithium battery according to the present invention.

4 (a) and 4 (b) are cross-sectional views of the main parts showing a second embodiment of the electrode terminal sealing apparatus of the lithium battery of the present invention.

5 is a sectional view showing the principal parts of a third embodiment of an electrode terminal sealing apparatus of a lithium battery according to the present invention;

6 is a sectional view showing the principal parts of a fourth embodiment of an electrode terminal sealing apparatus of a lithium battery according to the present invention;

Explanation of symbols on the main parts of the drawings

200 .... Lithium battery 210 .... Rivet

220 .... upper cap 210a, 220a .... rivet and sealing of upper cap

230a, 230b .... upper and lower gaskets

240a, 240b .... 1st and 2nd sealing member

As a technical means for achieving the above object, the present invention, at least one of the first sealing member is installed to increase the closeness to the gasket in the sealing portion of the upper cap is pressed in the upper, lower gaskets Wow,

By providing an electrode terminal sealing device of a lithium battery comprising at least one or more second sealing member is installed to increase the tightness of the lower gasket and the sealing portion of the rivet coupled to the lower gasket.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a cross-sectional view showing a first embodiment of an electrode terminal sealing apparatus of a lithium battery according to the present invention. The present invention is constituted as a first sealing member 240a and a second sealing member 240b.

The anode lead 202 connected to the cathode plate 201 wound therein is connected to the rivet 210 which is the anode terminal through the spacer 203 so that the cover plate 208 is coupled to the outer circumferential surface of the rivet 210. Lithium cap is sealed by sealing the upper cap 220 and the gaskets 230a and 230b which are negative terminals coupled to the upper side of the rectangular case 207 connected to the negative electrode lead 206 of the negative electrode plate 205. The battery 200 is provided.

In addition, the first sealing member 240a for increasing the tightness between the upper and lower gaskets 230a and 230b and the upper cap 220 serving as the negative electrode terminal is compressed with the upper and lower gaskets 230a. The contact surface to be coupled is integrally installed with at least one or more in the sealing portion 220a of the upper cap 220. In addition, the second sealing member 240b to increase the tightness between the rivet 210 and the lower gasket 230b is a sealing portion of the rivet 210 which is a contact surface closely coupled to the lower gasket 230b. It is made of a configuration that is integrally installed with at least one (210a).

As shown in FIG. 3, the electrode terminal sealing apparatus of the present invention having the above structure is wound around the inside of the rectangular case 207 of the rectangular lithium ion secondary battery 200 about 8 times and has a jelly-shaped positive electrode plate ( The positive lead 202 connected to the 201 is connected to the rivet 210 while being folded through the spacer 203, whereby the rivet 210 becomes a positive terminal of the lithium battery 200, wherein the spacer 203 is The internal pressure of the lithium battery 200 is adjusted, the electrolyte injection operation is controlled, and a perforated network is formed.

Meanwhile, the negative electrode lead 206 connected to the negative electrode plate 205 wound to the outside of the positive electrode plate 201 is connected to the case 207 so that the case 207 becomes a negative electrode terminal. The upper cap 220 coupled to the upper side is also integrally a negative electrode terminal, wherein the negative lead 206 and the rivet 210 that is the positive electrode terminal are insulated as an insulating tape 204.

In addition, the upper and lower gaskets 230a and 230b are insulated between the upper cap 220, which is a negative electrode terminal, and the rivet 210, which is a positive electrode, to prevent a short, and the upper and lower gaskets 230a, ( 230b) is pressed and coupled to the rivet 210 integrally from the upper and lower sides of the upper cap 220. At this time, the electrolyte is injected through the injection hole 220b installed in the upper cap 220, and then, when the fixing ball 220c is sealed by laser or spot welding, the electrolyte is sealed with the rivet 210. External leakage is prevented as the upper and lower gaskets 230a and 230b that are compressed together, and thus the upper and lower gaskets 230a and 230b are insulated from the electrode terminals 210 and 220. It is to maintain the sealing state of (200).

In addition, at least one first sealing member 240a made of at least one unevenness is installed in the sealing portion 220a of the upper cap 220, which is an inner contact surface closely coupled to the upper and lower gaskets 230a and 230b. By doing so, the first sealing member 240a further improves the sealing state of the lithium battery 200 by making the upper or lower gaskets 230a and 230b closely adhere to the upper cap 220. In particular, the sealing state between the gasket 230 and the upper cap 220 is further strengthened as the first sealing member 240a in the longitudinal direction as well as in the transverse direction.

At this time, the rivet 210 and the second sealing member 240b made of at least one unevenness may also be installed in the sealing portion 210a of the rivet 210, which is an inner contact surface closely coupled to the lower gasket 230b. When the compression bonding of, the sealing state between the lower gasket 230b and the rivet sealing portion 210a becomes more tightly.

Accordingly, the sealing state between the upper and lower gaskets 230a and 230b and the upper cap 220 and the rivet 210 becomes more tight as the first and second sealing members 240a and 240b. Due to the external leakage of the electrolyte is prevented, and manufacturing and assembly work can be performed smoothly.

4 (a) and 4 (b) are cross-sectional views of main parts showing a second embodiment of an electrode terminal sealing apparatus of a lithium battery according to the present invention, the first sealing member 240a 'of the upper cap 220 The thickness of the sealing portion 220a is opposed to each other, or mutually installed to strengthen the sealing state.

Therefore, in the second embodiment of the present invention in which the first sealing member 240a 'is provided to face each other or cross each other, the upper cap 220 and the upper and lower gaskets 230a and 230b are riveted. When the compression bonding with the 210, the upper and lower two points at the opposite or intersecting to be integrally interlocked by the compression bonding, thereby maintaining a more tight adhesion between the upper cap 220 and the gasket 230 to maintain the lithium battery 200 The sealing state of the can be strengthened more.

FIG. 5 is a cross-sectional view of a main part of a third embodiment of an electrode terminal sealing apparatus of a lithium battery according to an embodiment of the present invention. By integrally forming the first sealing member 240a ", molding of the first sealing member 240a" is extremely easy in the injection molding of the upper cap 220, which is the first sealing member 240a ". In order to form a) it is possible to simply manufacture without increasing the thickness of the upper cap 220.

6 is a sectional view showing main parts of a fourth embodiment of an electrode terminal sealing apparatus of a lithium battery according to the present invention, wherein the first and second sealing members 240a and 240a 'of the first, second and third embodiments are shown.

240a "and 240b are formed in a T-shape rather than an uneven | corrugated shape, and the contact area between the gasket 230, the rivet 210, and each sealing member 240a, 240a ', 240a", 240b is determined. By enlarging it, the sealing state is greatly strengthened.

Accordingly, the sealing state between the upper and lower gaskets 230a and 230b and the electrode terminal rivet 210 and the upper cap 220 becomes extremely tight, thereby preventing external leakage of the electrolyte solution in advance. The first and second sealing members 240a and 240b may be easily manufactured and assembled without changing the shapes of the td 230 or the rivet 210 and the upper cap 220.

As described above, according to the electrode terminal sealing apparatus of the lithium battery of the present invention, the sealing state between the gasket and the upper cap, which is the electrode terminal, and the rivet becomes even closer, thereby preventing battery defects due to the short insulation due to the solid insulation of the electrode terminals. At the same time, the external leakage of the internal electrolyte is effectively blocked to prolong the service period, and prevent damage to the battery manufacturing apparatus or the equipment due to the leakage of the electrolyte, and has an excellent effect of increasing the product reliability of the lithium battery.

Claims (5)

An anode lead 202 connected to the inner anode plate 201 is connected to the rivet 210 which is the anode terminal through the spacer 203, and an anode terminal which is connected to the cathode lead 205 on the outer circumferential surface of the rivet 210. In the electrode terminal sealing structure of the lithium battery 200 in which the cap 220 and the upper and lower gaskets 230a and 230b are sequentially pressed and coupled, At least one first sealing member installed to increase tightness with the gasket 230 in the sealing portion 220a of the upper cap 220 that is press-fitted in the upper and lower gaskets 230a and 230b. 240a), and At least one second sealing member (240b) is provided in the sealing portion (210b) of the rivet 210 in close contact with the lower gasket (230b) is installed to increase the tightness with the lower gasket (230b). Terminal sealing device for lithium batteries The electrode terminal sealing apparatus of claim 1, wherein the first and second sealing members 240a and 240b are formed of irregularities. The electrode terminal sealing apparatus of claim 1, wherein the first sealing member 240a ′ is installed to face the thickness of the sealing portion 220a of the upper cap 220. The electrode terminal sealing apparatus of claim 1, wherein the first sealing member 240a "is integrally formed at the inner end of the upper cap sealing portion 220a. The electrode terminal sealing apparatus of any one of claims 1 to 4, wherein the first and second sealing members 240a, 240a ', 240a', and 240b are formed in a T-shape.