KR20140131032A - An electric energy storage device - Google Patents

Abstract

The electric energy storage device of the present invention includes: a cylindrical case which has an opened upper and an opened lower part to receive an electrode winding body; a lower cover terminal which is combined to shield the opened lower part of the case and charges at least one of a positive pole and a negative pole from the electrode winding body; an upper cover terminal which is combined with the opened upper part of the case, and charges the other from the electrode winding body, and discharges a gas generated in the case; and an active type gas discharge terminal part which is combined with the upper cover terminal and automatically opens or closes the injection hole by corresponding to the internal pressure of the case due to the gas. Thereby, the electric energy storage device can improve durability life and can prevent the breakage of the case at the same time by discharging the gas to the outside of the case, by actively corresponding to the gas pressure in the case. The electric energy storage device realizes the miniaturization of a product without forming a separate gas storage space.

Description

[0001] AN ELECTRIC ENERGY STORAGE DEVICE [0002]

The present invention relates to an electric energy storage device, and more particularly, to an electric energy storage device having an active gas discharge terminal portion so that gas is actively discharged to the outside in response to an internal pressure generated by an internal gas, And more particularly to an electric energy storage device capable of simplifying a structure and capable of compact designing.

A secondary battery capable of charging and discharging like a capacitor as compared with a primary battery capable of only discharging has a great influence on the resistance and efficiency of the secondary battery according to the connection method of a terminal for electrically connecting an internal current source and an external resistor The productivity of the secondary battery itself and the convenience of the user who uses the secondary battery are greatly influenced.

Accordingly, there is a strong demand for a terminal connection method that can function as a secondary battery and increase the electric capacity and reduce the internal resistance, and an electric energy storage device using the terminal connection method.

1 is a perspective view showing an example of a cylindrical electric energy storage device according to the prior art.

1, a cylindrical electric energy storage device 1 according to the related art is provided with an upper and a lower opening so that a core (not shown) and an electrode winding body (not shown) wound on the core are accommodated, And an upper cover 20 and a lower cover (not shown) coupled to upper and lower portions of the case 10. The upper cover 20 is provided with a positive terminal and a negative terminal 30 are protruded.

However, an example of the conventional cylindrical electric energy storage device 1 according to the related art is that when the gas which is unavoidably generated during operation is accumulated in the case 10, the pressure excessively rises, The case 10 may be deformed.

Particularly, in order to prevent explosion, a metal or polymer membrane is ruptured by the pressure of the gas in the case 10, and after the metal or polymer membrane is ruptured, Is terminated.

In recent years, a technique has been developed to delay the rise of internal pressure by gas by forming a predetermined gas storage space so that gas can be accumulated in the case 10 in order to extend its service life. Which causes a problem that the weight and volume of the storage device become large.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an electric energy storage device capable of preventing the case from being damaged due to gas accumulation therein and realizing compactness of the product, And the like.

An electric energy storage device according to the present invention includes: a cylindrical case having upper and lower openings for accommodating an electrode winding body; and at least one of an anode and a cathode from the electrode winding body, A lower cover terminal for collecting one polarity; a lower cover terminal coupled to an upper opened portion of the case, for collecting the remaining one polarity from the electrode winding body and having a discharge hole through which gas generated inside the case is discharged; And an active gas discharge terminal portion which is coupled to the upper cover terminal and automatically opens or closes the discharge hole corresponding to the internal pressure of the case by the gas.

The active gas discharge terminal portion is fixed to the outside of the upper cover terminal on which the discharge hole is formed to cover the discharge hole and has a discharge gas discharge hole for guiding gas discharged from the discharge hole to the outside, Wow; And a plunger movably disposed by the gas discharged from the discharge hole in the discharge gas discharge hole, wherein the gas can be discharged to the discharge gas discharge hole when the plunger moves. Here, the plunger may be elastically supported in the discharge gas discharge hole.

The lower end of the discharge gas discharge hole is provided with a guide hole smaller than an inner diameter of the discharge gas discharge hole and an upper end of the discharge gas discharge hole is provided with a communication hole having an inner diameter smaller than the inner diameter of the discharge gas discharge hole, The plunger may be elastically supported by an elastic member provided between the plunger and the elastic member supporter.

Further, a guide hole opening / closing member interlocked with the plunger and covering an upper end of the guide hole may be provided between the plunger and the guide hole.

The discharge gas discharge hole may be formed in a circular shape, the plunger may be formed in a polygonal shape, or the discharge gas discharge hole may be formed in a circular shape, the plunger may be formed in a circular shape to be inserted into the discharge gas discharge hole, A gas discharge path through which the gas is discharged between the discharge gas discharge hole and the discharge gas discharge hole may be formed.

The upper cover terminal may have a mounting hole formed at an upper surface of the upper cover terminal to receive a lower end of the connection terminal, and the connection terminal may be screwed into the mounting hole.

The coupling terminal may be provided with a flange portion for supporting a portion of the upper surface of the upper cover terminal corresponding to the rim of the installation hole, and a first seal may be interposed between the flange portion and the upper cover terminal.

The flange portion corresponding to the outer side of the first sealing may be formed with an inclined portion for pressing the step formed on the coupling terminal when the coupling terminal is screwed to the installation hole.

The upper cover terminal may be coupled to the case such that the upper cover terminal is hooked to the upper end of the latching rib via a second sealing which surrounds the rim of the upper cover terminal . Here, the upper end of the case may be formed inward so as to surround the upper end of the second ceiling.

An electrolyte storage portion in which the internal electrolyte inside the case is accumulated can be formed between the upper cover terminal and the electrode winding body with the installation hole therebetween.

A first gas storage portion for storing the gas may be formed between the discharge hole and the guide hole.

The lower cover terminal, the electrode lead portion, and the lower end of the case may be welded together by laser welding.

The electric energy storage device according to the present invention actively responds to the pressure inside the case due to accumulation of gas inside the case and discharges the gas to the outside of the case, thereby preventing damage to the case and improving durability life I have.

Further, since the electric energy storage device according to the present invention actively discharges the gas to the outside of the case, there is no need to form a separate gas storage space, and the effect of realizing miniaturization (compacting) of the product can be achieved I have.

In addition, since the electric energy storage device according to the present invention has a simple structure, it has an effect of improving the assemblability.

1 is a perspective view illustrating an example of an electric energy storage device according to the related art,
2 to 4 are cross-sectional views illustrating a manufacturing procedure of an electric energy storage device according to a preferred embodiment of the present invention,
Fig. 5 is an enlarged view of a portion A in Fig. 4,
6 is a cross-sectional view showing another embodiment of the electric energy storage device according to the present invention.

Hereinafter, embodiments of an electric energy storage device according to the present invention will be described in detail with reference to the accompanying drawings.

FIGS. 2 to 4 are cross-sectional views illustrating a manufacturing procedure of an electric energy storage device according to a preferred embodiment of the present invention, and FIG. 5 is an enlarged view of a portion A of FIG.

As shown in FIG. 2, a preferred embodiment of the electric energy storage device according to the present invention includes a cylindrical case 110 having upper and lower openings for receiving the electrode winding body 130 wound around the winding core 120, A lower cover terminal 160 and an upper cover terminal 170 which are respectively coupled to lower and upper portions of the case 110. The upper cover terminal 170 and the discharge hole 175) for automatically opening or closing the gas exhaust terminal unit 200.

Here, the lower cover terminal 160 is coupled to completely shield the opened lower portion of the case 110, and collects the polarity of at least one of the positive electrode and the negative electrode from the electrode take-up body 130, 170 are coupled to the open upper portion of the case 110, and collect the remaining one polarity from the electrode winding body 130. The upper cover terminal 170 is formed with a discharge hole 175 through which gases generated in the case 110 are discharged.

The core 120 is disposed vertically in the middle of the inside of the case 110 and the electrode winding unit 130 is wound around the core 120 to form an inner circumferential surface of the case 110 Lt; / RTI > The electrode winding unit 130 wound around the winding core 120 is accommodated in the cylindrical case 110 according to the embodiment of the present invention. However, even if the electrode winding unit without the winding core is housed in the case 110, Do.

A lower connection member 140 is connected to a lower end of the electrode winding body 130 and a rim 141 is bent downward. The lower connection member 140 surrounds the lower cover terminal 160 and mediates coupling of the lower cover terminal 160 to the inside of the lower end of the case 110.

The lower cover terminal 160 is connected to the lower end of the electrode winding body 130 so as to cover a lower electrode lead portion (not shown) provided as an aluminum foil material, The inner surface of the lower end of the case 110 and the lower connecting member 140 can be coupled at the same time by welding so that assembly is facilitated.

In addition to the laser welding, a coupling member insertion groove 161 is formed in the lower cover terminal 160 to fasten the coupling member 195 to be inserted into the lower electrode lead portion. The lower cover terminal 160 Can be more firmly coupled to the fastening member insertion groove 161 of the fastening member 195 in a fastening manner.

An upper connecting member 150 is connected to an upper end of the electrode winding unit 130 and a rim 151 of the upper connecting member 150 is bent so as to cover an upper edge of the electrode winding unit 130. More specifically, an upper electrode lead portion (not shown) provided with an aluminum foil material is connected to the upper end of the electrode take-up member 130 so as to cover the upper electrode lead portion, And a rim of the upper connecting member 150 is connected so as to surround the rim of the upper electrode lead portion.

A locking rib 111 is formed at the upper end of the case 110 corresponding to the upper side of the upper connecting member 150 so as to protrude inward. The edge of the upper cover terminal 170 is hooked by the latching rib 111 so that the rim of the upper cover terminal 170 is spaced apart from the rim of the upper electrode lead part by a predetermined distance to thereby store the electrolyte solution in the electrolyte storage part 290 ). The electrolytic solution storage unit 290 is a place where the internal electrolytic solution collects. Especially when the module is constituted, when the electrolytic solution storage unit 290 is positioned downward, the electrolytic solution inside the cell is discharged through the discharge hole 175 Thereby providing a space in which the internal electrolyte solution is accumulated so as not to be discharged to the outside.

3, the upper cover terminal 170 is hooked to the latching rib 111 via a sealing ring 180 that surrounds the edge of the upper cover terminal 170. As shown in FIG. The seal 180 is hereinafter referred to as a " second seal 180 "in order to distinguish it from the seal 260 provided in the active gas exhaust terminal 200 described later.

The second sealing 180 is interposed between the inner circumferential surface of the case 110 and the upper cover terminal 170 so that the gas generated in the case 110 leaks to a portion of the outside of the discharge hole 175 .

The upper cover terminal 170 is formed with an installation hole (not shown) in which the center portion of the upper cover terminal 170 is depressed downward so that the active gas exhausting terminal unit 200 is installed. The discharge hole 175 is formed at the bottom of the mounting hole and the lower surface of the mounting hole is tightly coupled to the upper surface of the upper connecting member 150.

As described above, the rim of the upper cover terminal 170 is spaced upward from the rim of the upper connecting member 150 by a predetermined distance, and the electrolyte reservoir 290 is formed outside the mounting hole . That is, an electrolyte storage part 290 is formed between the upper cover terminal 170 and the electrode winding body 130 with the installation hole interposed therebetween.

The upper end of the case 110 is inwardly formed to enclose the upper end of the second ceiling 180, thereby firmly coupling the upper cover terminal 170. 3, the bottom of the upper cover terminal 170, which is in close contact with the upper surface of the upper connecting member 150, is laser-welded using a laser welder 190.

Meanwhile, an active gas exhausting terminal unit 200 is installed in the installation hole.

4 and 5, the active gas discharge terminal unit 200 is fixed to the outside of the upper cover terminal 170 on which the discharge hole 175 is formed so as to cover the discharge hole 175 A coupling terminal 210 formed with a discharge gas discharge hole 215 for guiding the gas discharged from the discharge hole 175 to the outside and a discharge port 215 for discharging the discharge gas from the discharge hole 175 to the discharge gas discharge hole 215 And a plunger 220 movably disposed by gas.

The coupling terminal 210 has a screw thread 171 formed at a lower end thereof to be inserted into the installation hole and to be coupled in a threaded manner. The discharge gas discharge hole 215 communicates with the discharge hole 175, And is vertically penetrated.

The coupling terminal 210 is formed with a flange portion 211 for supporting a part of the upper surface of the upper cover terminal 170 corresponding to the rim of the installation hole. The lower surface of the flange portion 211 is formed to be in contact with a part of the upper surface of the upper cover terminal 170.

A first sealing 260, which is distinguished from the second sealing 180, is interposed between the flange 211 and the lower end of the coupling terminal 210.

More specifically, the first sealing 260 is interposed between the flange portion 211 and the inner edge portion formed by the lower end of the coupling terminal 210, so that the coupling terminal 210, Thereby preventing the gas from leaking into the gap between the gasket 170 and the gasket.

The upper cover terminal 170 may have a seating groove on which the first ceiling 260 is seated. The mounting groove may include a step portion 172 formed to be perpendicular to the upper surface of the upper cover terminal 170 and a step portion 173 formed to be orthogonal to the mounting hole, Thereby forming a predetermined space in which the seal 260 is seated.

A portion of the lower surface of the flange portion 211 corresponding to the outer side of the first sealing ring 260 may be engaged with the stepped portion of the upper cover terminal 170 when the coupling terminal 210 is screw- 172 and 173 are pressed outward. More specifically, the inclined portion 213 is formed to be inclined so as to contact the edge of the stepped portion 172 formed perpendicularly to the upper surface of the upper cover terminal 170 among the stepped portions 172 and 173, When the coupling terminal 210 is screwed into the installation hole, the coupling terminal 210 moves downward and the inclined portion 213 contacts the edge of the step 211 while rubbing. Thus, a sealing effect that prevents the leakage of gas by the contact of the step portion 172 and the inclined portion 173 outside the first sealing 260 can be created.

Meanwhile, in the discharge gas discharge hole 215, the plunger 220 is provided to be movable by the pressure of gas accumulated in the case 110.

More specifically, the discharge gas discharge hole 215 is formed to have a circular horizontal section having a predetermined inner diameter. The lower end of the discharge gas discharge hole 215 is communicated with the discharge hole 175 so as to prevent the gas from leaking between the coupling terminal 210 and the installation hole so as to be in contact with the upper surface of the discharge hole 175 Respectively. The discharge gas discharge hole 215 is formed at the lower end of the discharge gas discharge hole 215 so that the gas discharged through the discharge hole 175 is smaller than the discharge gas discharge hole 215, And the lower end of the plunger 220 is engaged by forming the hole 217.

Meanwhile. The plunger 220 is sized to be inserted into the discharge gas discharge hole 215 and has a substantially hexagonal shape so that gas flows between the inner surface of the discharge gas discharge hole 215 and the outer surface of the plunger 220. And is formed as a polygon having a horizontal cross section.

However, the plunger 220 does not need to be formed in a polygonal shape having a hexagonal horizontal cross section, and a separate gas discharge path (not shown) may be provided between the outer peripheral surface of the plunger 220 and the discharge gas discharge hole 215 May be formed so as to have a circular cross-section inserted into the discharge gas discharge hole 215 as long as the discharge gas discharge hole 215 is formed.

In addition, the plunger 220 is elastically supported in the discharge gas discharge hole 215. More specifically, an elastic member supporter 230 having a communication hole 231 smaller than the inner diameter of the discharge gas discharge hole 215 is formed at an upper end of the discharge gas discharge hole 215. An elastic member 240 is disposed between the plunger 220 and the elastic member supporter 230 to elastically support the plunger 220 toward the guide hole 217. The elastic member 240 may be a spring spring. However, it should be understood that the elastic member 240 is not limited to a spring, but includes any means for elastically supporting the plunger 220 toward the guide hole 217.

A guide hole opening and closing member 250 interlocked with the plunger 220 and covering the upper end of the guide hole 217 is provided between the plunger 220 and the guide hole 217. When the plunger 220 is elastically supported by the elastic member 240 toward the guide hole 217, the guide hole opening / closing member 250 covers the guide hole 217, It is possible to prevent the gas generated in the case 110 from leaking and also to prevent the gas generated in the case 110 from accumulating when the pressure of the gas exceeds the elastic force of the elastic member 240, And serves to discharge the gas while being separated from the guide hole 217. The guide hole opening and closing member 250 is preferably made of a rubber material.

Hereinafter, the operation of the electric energy storage device according to the present invention will be briefly described.

First, when a gas is generated in the case 110, the pressure inside the case 110 rises, and the guide hole opening / closing member 250 covering the guide hole 217 is opened And is separated from the guide hole 217 while being pushed upward.

When the guide hole opening and closing member 250 is separated from the guide hole 217, the plunger 220 is moved upward from the discharge gas discharge hole 215, and the elastic force of the elastic member 240 Gas is discharged between the inner surface of the discharge gas discharge hole 215 and the outer surface of the plunger 220 until the inner pressure of the case 110 becomes small. This is because the plunger 220 is formed in a polygonal shape to be inserted into the discharge gas discharge hole 215 and a space is formed between the discharge gas discharge holes 215 by the plunger 220 as described above.

The gas thus discharged is finally discharged to the outside through the communication hole 231 formed in the elastic member supporter 230.

Since the gas generated inside the case 110 is prevented from leaking arbitrarily by the first sealing 260 and the second sealing 180, the gas generated in the case 110 The internal pressure of the case 110 can be raised normally and the case 110 can be prevented from being damaged by discharging the gas by the active gas exhausting terminal unit 200 in conjunction with the pressure rise inside the case 110. [ There is no need to provide a separate gas accumulation space as well as an advantage of miniaturization of the product.

6 is a cross-sectional view illustrating another embodiment of the electric energy storage device of the present invention.

As compared with the above-described preferred embodiment, the electric energy storage device according to the present invention has substantially the same configuration as that of the above-described preferred embodiment, but includes a lower cover terminal 160 for substantially supplying power to the outside, (310) is further protruded in the longitudinal direction of the case (110).

6, the coupling terminal 310 may be formed in a manner that the guide hole 217 does not come in contact with the discharge hole 175 and is spaced apart from the discharge hole 175 And a storage unit 390B for storing the gas is formed between the discharge hole 175 and the guide hole 217. [

The center portion of the lower cover terminal 160 protrudes downward by a predetermined length and the protruded portion constitutes a storage portion 390C in which the gas generated in the case 110 is stored.

A storage portion formed between the discharge hole 175 and the guide hole 217 is defined as a first gas storage portion 390B and a storage portion formed in the lower cover terminal 160 is defined as a second gas And is defined as a storage unit 390C.

According to another embodiment of the electric energy storage device of the present invention, since the first gas storage portion 390B and the second gas storage portion 390C are provided, the volume of the product is increased, The terminal 160 and the coupling terminal 210 are further protruded in the vertical direction, so that it is possible to more actively cope with the pressure due to accumulation of gas in the case 110. [

Embodiments of the electric energy storage device according to the present invention have been described in detail with reference to the accompanying drawings. However, it should be understood that the embodiments of the present invention are not necessarily limited to the above-described preferred embodiments, and that various modifications and equivalents may be made by those skilled in the art something to do. Therefore, it is to be understood that the true scope of the present invention is defined by the appended claims.

110: Case 120: Reach
130: electrode winding unit 140: lower connection member
150: upper connecting member 160: lower cover terminal
170: upper cover terminal 180: second sealing
200: active gas exhaust terminal part 210:
220: plunger 230: elastic member supporter
240: elastic member 250: guide hole opening / closing member
260: First sealing

Claims (16)

A cylindrical case having upper and lower openings for receiving the electrode winding body;
A lower cover terminal coupled to shield the opened lower portion of the case, for collecting the polarity of at least one of an anode and a cathode from the electrode winding body;
An upper cover terminal coupled to an upper opened portion of the case and configured to collect the other polarity from the electrode winding body and having a discharge hole through which gas generated inside the case is discharged;
And an active gas discharge terminal portion coupled to the upper cover terminal for automatically opening or closing the discharge hole corresponding to an internal pressure of the case by the gas. The method according to claim 1,
The active gas exhaust terminal unit includes:
A coupling terminal fixed to the outside of the upper cover terminal formed with the discharge hole to cover the discharge hole and having a discharge gas discharge hole for guiding gas discharged from the discharge hole to the outside;
And a plunger movably arranged by the gas discharged from the discharge hole in the discharge gas discharge hole,
And the gas is discharged to the discharge gas discharge hole when the plunger moves. The method of claim 2,
And the plunger is resiliently supported in the discharge gas discharge hole. The method of claim 3,
Wherein the discharge gas discharge hole has a guide hole formed at a lower end portion thereof smaller than the inner diameter of the discharge gas discharge hole and an upper end portion of the discharge gas discharge hole is provided with a communication hole smaller than the inner diameter of the discharge gas discharge hole,
Wherein the plunger is elastically supported by an elastic member provided between the plunger and the elastic member supporter. The method of claim 4,
And a guide hole opening / closing member interlocked with the plunger and covering an upper end portion of the guide hole between the plunger and the guide hole. The method of claim 5,
Wherein the guide hole opening / closing member is made of a rubber material. The method of claim 2,
Wherein the discharge gas discharge hole is formed in a circular shape, and the plunger is formed in a polygonal shape. The method of claim 2,
Wherein the discharge gas discharge hole is formed in a circular shape and the plunger is formed in a circular shape to be inserted into the discharge gas discharge hole and a gas discharge path through which the gas is discharged is formed between the discharge gas discharge hole and the discharge gas discharge hole. The method of claim 2,
A mounting hole in which a lower end of the coupling terminal is coupled is formed in an upper surface of the upper cover terminal,
And the coupling terminal is screwed to the installation hole. The method of claim 9,
A flange portion for supporting a part of an upper surface of the upper cover terminal corresponding to a rim of the installation hole is formed in the coupling terminal,
And a first sealing is interposed between the flange portion and the upper cover terminal. The method of claim 10,
Wherein the flange portion corresponding to the outside of the first seal has an inclined portion for pressing a step formed on the coupling terminal when the coupling terminal is screwed to the installation hole. The method according to claim 1,
A locking rib is formed on the upper end of the case so as to project inward,
Wherein the upper cover terminal is coupled to the case such that the upper cover terminal is engaged with the upper end of the latching rib via a second sealing surrounding the rim of the upper cover terminal. The method of claim 12,
Wherein an upper end of the case is inwardly formed to enclose an upper end of the second seal. The method of claim 9,
And an electrolytic solution storing portion in which an inner electrolytic solution in the case is held with the mounting hole therebetween is formed between the upper cover terminal and the electrode winding body. The method of claim 4,
And a first gas storage part for storing the gas is formed between the discharge hole and the guide hole. The method according to claim 1,
An electrode lead portion of aluminum material is further provided between the lower cover terminal and the electrode winding body,
And the lower cover terminal, the electrode lead portion, and the lower end of the case are welded by laser welding.

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