KR20150095158A - Battery cover - Google Patents

Abstract

The present invention relates to a battery cover. More specifically, the battery cover comprises: a main body which is formed to open and close the upper side of a case wherein an electrolyte is charged; a gas outlet to discharge gas generated inside the case to the outer side of the case by being included on the lower side of the main body; and a gas inlet which is included in the gas outlet to introduce the gas generated inside the case to the gas outlet from a predetermined position. The gas inlet comprises: a body which is extended from the gas outlet as a predetermined length which of an upper end is opened and a space unit communicated with the gas outlet is formed in the inner side; an inner wall to guide the gas introduced to the space unit to the gas outlet by being formed inside the space unit; and a cover which is combined to the upper side of the body to be able to rotate and open and close the upper side of the body and form an opening unit on both sides of an edge to pass the gas from inside the case to the space unit. The battery cover of the present invention can be easily manufactured by being made as a single-layered structure and prevent the leakage of an electrolyte through a blocking unit which is formed in a maze structure.

Description

Battery cover {Battery cover}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a battery cover, and more particularly, to a battery cover which is coupled to a case of a battery using an electrolyte to discharge gas generated therein, while preventing leakage of the electrolyte.

A typical battery is classified into a primary battery and a rechargeable secondary battery, and a large-capacity battery uses an electrolyte. This liquid electrolyte must be provided with a separate security device. First, the electrolyte must not leak to the outside, and the gas generated by the chemical reaction must be released to the outside to prevent explosion.

BACKGROUND ART Conventional batteries largely consist of a former (hereinafter referred to as a case) in which an electrolyte is filled and a cover covering the case. The cover has a double structure of a lower cover formed with a terminal, a pull holding portion, and an upper cover.

The bottom cover has a partition wall corresponding to a cell formed in the case and the case, the partition being covered with the upper cover in addition to the terminal and the handle holding part. The bottom surface of the upper cover includes partition walls corresponding to the partition walls, And an explosion-proof filter for discharging the gas and blocking the electrolyte from passing therethrough.

The explosion-proof filter also serves to prevent the exhaust gas and the electrolyte solution from reacting with the external ignition, thereby preventing the explosion of the battery.

In this conventional cover structure, the upper cover covers the periphery of the water return port to form a labyrinth path, which means that the electrolytic solution flowing through the water return port flows easily into the water returning part, which is a certain space formed by fastening the upper and lower covers . Further, the water return port located at the lower side is arranged to return the electrolytic solution introduced into the water returning portion to the case.

As described above, the conventional cover is made of an upper and lower two-layer structure for the reason that the inside of the cover needs to be formed in consideration of the prevention of the inflow of the electrolyte, the discharge of the exhaust gas, the prevention of the explosion, and the reduction of the electrolyte introduced into the water-

However, such a two-layered cover requires a process corresponding to each of the upper and lower portions, a process for fastening the upper cover and the lower cover, and the productivity is lowered.

KR 10-1285055 B1

It is an object of the present invention to provide a battery cover which is easy to produce, can easily discharge gas generated therein, and can prevent leakage of an electrolyte solution.

According to an aspect of the present invention, there is provided a battery cover comprising: a body formed to open and close an upper portion of a case filled with an electrolyte; A gas discharge unit provided on a bottom surface of the main body to discharge gas generated inside the case to the outside of the case; And a gas inflow part provided in the gas discharge part so that gas generated inside the case can be introduced into the gas discharge part at a designated position.

The gas inlet includes a body having a predetermined length extending from the gas outlet, an upper end opened, and a space communicating with the gas outlet, the gas outlet being formed inside the space, And a cover which is rotatably coupled to an upper portion of the body to open and close an upper portion of the body and has openings formed on both sides of the edge so that gas can pass from the inside of the case to the space, .

The inner wall has a central inner wall formed to partition the space part into a first space part and a second space part respectively in the left and right direction and a gas introduced into the first space part through an opening provided at one side of the lid, So that the gas introduced into the second space can be moved to the gas discharging part along the second inflow path through the opening provided in the other side of the lid. And the gas discharge portion is formed with a communication hole for communicating the space portion and the gas discharge portion in an area corresponding to an end point of the first inflow path and the second inflow path, respectively, do.

And one side of the body is further provided with a bypass hole for introducing the gas in the case into the space when the opening of the lid is closed by the electrolytic solution filled in the case.

And a blocking part inserted into the gas discharging part to allow gas flowing into the gas discharging part through the gas inflow part and to block leakage of the electrolytic solution in the case.

Wherein the blocking portion includes a body having a pipe structure having an outer diameter corresponding to an inner diameter of the gas discharging portion and having a hollow portion formed therein and a lower portion thereof being opened and an electrolytic solution moving along the inside of the body when the electrolytic solution enters the hollow portion, And a plurality of shielding films coupled to the inside of the body to form mutually staggered or zigzag structures in the body.

The battery cover according to the present invention can be manufactured in a single layer structure and is easy to produce, and can easily discharge the gas generated therein, and can prevent the leakage of the electrolyte through the cutoff portion formed in the labyrinth structure.

1 is a perspective view of a battery having a battery cover according to the present invention;
2 is a perspective view showing a rear surface of the battery cover shown in FIG. 1;
3 is an enlarged perspective view of the gas inlet shown in Fig.
4 is a perspective view showing the back surface of the gas inlet shown in Fig.
5 is a plan view of the gas inlet shown in Fig.
6 is a plan view showing another embodiment of the gas inlet.
7 is a plan view showing another embodiment of the gas inlet.
8 is a plan view showing another embodiment of the gas inlet.
9 is a partially cutaway perspective view showing still another embodiment of the gas inlet.
10 is an exploded perspective view of a battery cover according to the present invention having a blocking portion;
11 is a cross-sectional view of the blocking portion shown in Fig.
12 is a cross-sectional view showing another embodiment of the blocking portion shown in Fig.
13 is a perspective view showing still another embodiment of the battery cover.
Fig. 14 is an exploded perspective view showing the gas inflow portion shown in Fig. 13; Fig.
15 is a perspective view showing still another embodiment of the battery cover.

Hereinafter, a battery cover according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 5 show a battery cover according to the present invention.

1 to 5, a battery cover 1 according to the present invention includes a main body 10 configured to open and close an upper portion of a case 2 filled with an electrolyte solution; A gas discharge unit 20 provided on a bottom surface of the main body 10 to discharge gas generated in the case 2 to the outside of the case 2; And a gas inflow part 30 provided in the gas discharge part 20 so that gas generated in the case 2 can be introduced into the gas discharge part 20 at a designated position.

The main body 10 is provided with a terminal 11 and a handle accommodating portion 12 on its upper surface and is provided at a position corresponding to the cell separating wall formed in the case 2 along the longitudinal direction on the bottom surface thereof, 13, and the gas discharge portion 20 extends in a direction passing through the partition wall 13. As shown in FIG.

The partition wall 13 is a portion to be fastened corresponding to a cell partition wall constituting a plurality of partitioned cells inside the case 2 and is provided with guide projections for facilitating fastening with the cell separation wall of the battery case 2 (14) are formed.

The gas discharge unit 20 discharges the gas generated by the chemical reaction of the electrolytic solution filled in the case 2 to the outside of the case 2, Is integrally formed with the main body 10 along the direction of the main body 10, and is formed into a pipe structure having a passage therein.

3, communicating holes 21 are formed in the outer circumferential surface of the gas discharging portion 20 so as to allow the internal space of the case 2 and the passages to communicate with each other. In the communicating hole 21, Are preferably formed at a position corresponding to a point where a gas inflow section 30 described later is located.

The gas inlet 30 includes a body 31 having a predetermined length extending from the gas outlet 20 and having an upper end opened and a space communicating with the gas outlet 20 by a communication hole 21, An inner wall formed in the space portion and guiding a gas introduced into the space portion to the gas discharge portion 20 and an upper portion of the body 31 rotatably coupled to the upper portion of the body 31, And a cover 34 having openings 34a formed on both sides of the edge of the case 2 so that gas can pass through the space.

The body 31 is formed in the shape of a quadrangular prism with an opened top. One of the side walls located in a direction orthogonal to the longitudinal direction of the gas discharge portion 20 is longer than the other side wall And the upper ends of both side walls located in a direction parallel to the longitudinal direction of the gas discharge portion 20 are formed to be inclined.

In this embodiment, the body has a hollow quadrangular prism shape. Alternatively, the body may have various shapes such as a circular prism or a polygonal prism.

The inner wall includes a central inner wall 33a, a left inner wall 33b, and a right inner wall 33c.

The central inner wall 33a is formed between the opposite side walls of the body 31 so as to partition the space portion of the body 31 into the first space portion 32a and the second space portion 32b in the left- As shown in FIG.

The left inner wall 33b is connected to the gas discharge portion along the first inflow path P1 through the opening portion 34a provided on one side of the lid 34, As shown in FIG.

The first inflow path P1 is a path that proceeds from the point corresponding to the left opening 34a of the lid 34 toward the center inner wall 33a to the right and then downwardly to the left again.

A gas flowing along the first inflow path (P1) is introduced into the outer circumferential surface of the gas discharging portion (20) corresponding to the end point of the first inflow path (P1) A communication hole 21 for communicating the space portion 32a and the gas discharge portion 20 is formed.

The right inner wall 33c flows into the second space 32b through the opening 34a provided on the other side of the lid 34 to be described later, And is formed to be able to move to the gas discharge portion along the inflow path P2.

The right inner wall 33c is formed symmetrically with the left inner wall 33b with respect to the central inner wall 33a and the second inflow path P2 formed by the right inner wall 33c is formed symmetrically with respect to the central inner wall 33a The first flow path P1 is symmetrical with respect to the first flow path P1.

The second inflow path P2 extends from the point corresponding to the right opening 34a of the lid 34 toward the center inner wall 33a to the left and extends to the right by folding downward.

The gas flowing through the second inflow path P2 may be introduced into the gas discharging unit 20 so that the gas moving along the second inflow path P2 may flow into the gas discharging unit 20 at a position corresponding to the end of the second inflow path P2. And a communication hole 21 for communicating the space portion 32b and the gas discharge portion 20 are formed respectively.

In order to extend the lengths of the first inflow path P1 and the second inflow path P2 in the central inner wall 33a, the left inner wall 33b, the right inner wall 33c and the body 31, Extension walls 35 extending a predetermined length toward the first inlet path P1 and the second inlet path P2 are formed.

When the opening 34a of the lid 34 is closed by the electrolytic solution filled in the case 2 as shown in Fig. 4, A bypass hole 31c may be formed at one side of the body 31 so that gas can be introduced into the space.

4, the bypass hole 31c is formed in a side wall of a long side of the opposite side walls of the body 31, and the center inner wall 33a and the dust- And is formed at a position spaced downward from the upper end of the body 31 by a predetermined distance and adjacent to the gas discharging portion 20. [

The bypass hole 31c is formed so as to pass through the body 31 and the gas inside the case 2 can flow into the first space portion 32a even when the opening portion 34a of the lid 34 is not closed by the electrolytic solution. And the second space 32b.

The gas inlet 30 formed with the bypass hole 31c as described above is configured such that the gas inside the case 2 passes through the bypass hole 31c when the opening 34a of the lid 34 is closed by the electrolytic solution The gas can be introduced into the space portion and can be introduced into the gas discharge portion 20. Even when the opening portion 34a of the lid 34 is not closed, the opening portion 34a of the lid 34 and the bypass hole 31c The gas inside the case 2 can be introduced into the space portion and introduced into the gas discharge portion 20. [

The cover 34 is rotatably coupled to the upper end of the shorter side wall of the body 31 and has an opening 34a at the other corner.

The opening 34a is formed by opening the cover 34 so that the gas inside the case 2 can be introduced into the space portion when the lid 34 closes the upper portion of the body 31, The length of the side wall is larger than the length of the side wall.

6 shows another example of the gas inlet 130. In FIG.

Referring to FIG. 6, the inner wall of the gas inlet 130 includes a central inner wall 133a, a first partition wall 133b, and a second partition wall 133c.

5, the central inner wall 133a of the body 31 is divided into a first space portion 32a and a second space portion 32b so as to divide the space portion of the body 31 into left and right directions, And extends across both side walls facing each other.

The first partition wall 133b is formed by a first inflow path P11 having a zigzag structure and a gas introduced into the first space portion 32a through an opening portion 34a provided at one side of the cover 34, To guide the gas to the gas discharging part 20 along at least one side thereof.

The first partitioning walls 133b are spaced apart from each other along the longitudinal direction of the gas discharging part 20 by a predetermined distance. One end of the first partitioning wall 133b is connected to the body 31, Are spaced apart from the body 31 and alternately arranged on opposite side walls of the body 31, respectively.

The second partitioning wall 133c is formed in such a manner that the gas flowing into the second space portion 32b through the opening portion 34a provided on the other side of the lid 34 contacts the first inner wall 133a with respect to the first inner wall 133a. And guides the gas to the gas discharging part 20 along a second inflow path P12 having a structure symmetrical with the inflow path P11, and at least one of them is provided.

The second partitioning walls 133c are spaced apart from each other by a predetermined distance along the longitudinal direction of the gas exhausting part 20, and one end of the second partitioning wall 133c is connected to the body 31, Are spaced apart from the body 31 and alternately arranged on opposite side walls of the body 31, respectively.

5 and 6, the gas inflow part according to the present invention may include a first partition wall 233b having an end portion branched into several branches as shown in FIG. 7, The first partitioning walls 333b and the second partitioning walls 333c may be inclined in one direction as shown in FIG. 8, as shown in FIG.

The gas inflow portion is not limited to the illustrated example and any structure can be used as long as it has a structure in which the inflow path of the gas flowing into the gas discharge portion 20 from the space portion in the body 31 can be formed as a labyrinth structure.

9, another embodiment of the gas inlet 430 is shown.

9, a bypass hole 431b is formed at one side of the body 431 in order to prevent the gas inlet 430 from being closed by the electrolyte when the opening 34a of the lid 34 is closed by the electrolytic solution.

The gas inlet portion 430 according to the present embodiment is arranged such that the body 431 is biased to one side orthogonal to the longitudinal direction of the gas outlet portion 20 with respect to the gas outlet portion 20, A part of the bottom 431d is exposed to the outside, more specifically, exposed to the inside space of the case.

A through hole 431b is formed in the bottom of the body 431, which is exposed to the outside, so as to communicate with the space in the body 431. The bypass hole 431b has the same function as the bypass hole 31b of the body 31 shown in Fig. 8 and the opening 34a of the lid 34 is closed by the electrolytic solution filled in the case The gas inside the case can be introduced into the space. That is, the gas can enter the space of the gas inlet 430 through the bypass hole 431b until the electrolytic solution reaches the height corresponding to the bottom of the body 431.

10 and 11, the battery cover according to the present invention is inserted into the gas discharging portion 20 to allow the gas flowing into the gas discharging portion 20 to pass through the gas inflow portion, And a blocking portion (40) for blocking the leakage of the electrolyte solution.

The blocking part 40 allows the gas flowing into the gas discharging part 20 through the communication hole 21 to be discharged to the outside and when the case is impacted or tilted, And is inserted into the gas discharge portion 20 so as to be blocked from flowing out to the outside through the discharge portion 20.

The blocking portion 40 has an open pipe structure body 41 having an outer diameter corresponding to the inner diameter of the gas discharge portion and having a hollow portion 41a formed therein and a plurality of holes spaced apart along the longitudinal direction, And a plurality of blocking membranes 45 coupled to form a staggered or zigzag structure in the body 41 so as to interfere with the electrolyte flowing along the inside of the body 41 when the electrolyte enters the hollow portion 41a do.

The blocking portion 40 prevents the leakage of the electrolytic solution by forming the labyrinth structure by the blocking membranes 45.

Another embodiment of the blocking portion is shown in Fig.

The cutout 140 includes a hollow 141a formed therein and a body 141 formed at a lower portion thereof with openings 141b communicating with the hollow 141a at predetermined intervals along the longitudinal direction thereof, And a partition wall 145 formed inside the body 141. [

The partition wall 145 is formed in the body 141 in a direction orthogonal to the longitudinal direction of the body 141 so as to partition the hollow portion 141a on both sides of each opening 141b, The gas flowing into the hollow portion 141a through the opening 141b passes through the partition wall 145 and the upper portion of the one partition wall 145 and the lower portion of the partition wall 145 on the other side, Respectively, through holes 145a.

The gas introduced into the hollow portion 141a through the opening 141b by the passage hole 145a formed in the upper portion of the one side partition wall 145 and the lower portion of the other side partition wall 145 as described above The electrolyte solution flowing into the hollow portion 141a through the opening 141b must reach the upper portion of the partitioning wall 145a on which the through hole is formed, so that it is difficult to pass through.

The battery cover according to the present invention further includes a filter unit 50 for discharging the gas, blocking the leakage of the electrolyte, preventing external deterioration from entering the case, and preventing explosion of the battery.

The filter unit 50 is inserted into both end portions of the gas discharge unit 20 and is fastened to the main body. The filter unit 50 includes a filter housing 51 coupled to the main body and an explosion-proof filter 55 disposed inside the filter housing 51.

13 and 14 illustrate a gas inlet according to another embodiment of the present invention. 13 and 14, the gas inlet 530 is formed to communicate with the gas outlet 20, extends in a direction orthogonal to the gas outlet 20, and has a space 531a therein An insert 535 inserted into the body 531 and a cover 535 connected to the upper end of the insert 535 to close the upper portion of the body 531. [ (537).

In the inside of the body 531, a seating jaw is formed to be inclined with respect to the longitudinal direction of the body 531 so that the lid 537 can be seated. An incision slit 531b, And extends to the bottom of the seating jaw. As shown in FIG. 4, when the cutting slit 531b formed on the body 531 is closed by the electrolytic solution at the middle portion between the upper end and the lower end of the body 531, A bypass hole 531c is formed so as to be able to flow in.

The insert 535 includes a bottom portion 535a that is seated on the bottom of the body 531, a column 535b that extends a predetermined length from the center of the bottom portion 535a, And a guide plate 535c formed in a spiral structure along the circumferential direction.

The guide plate 535c guides the gas passing into the body 531 through the cutting slit 531b to rotate around the column 535b and rotates around the column 535b to the inner peripheral surface of the body 531 It extends to a length that can be contacted. An opening 535a` is formed at one side of the bottom portion 535a to allow the communication hole 21 of the gas exhaust portion 20 and the space portion 531a in the body 531 to communicate with each other.

The lid 537 is formed in an elliptical structure so as to close the upper portion of the body 531. The lid 537 is coupled to close the space 531a of the body 531 when the insert 535 is inserted into the body 531, So that the body 531 can not be completely closed by the elastic member 531b. This allows the gas generated inside the case to be introduced into the space 531a of the body 531 through a part of the cutting slit 531b.

The gas which has passed through the cutting slit 531b and enters the space portion 531a inside the body 531 is guided around the column 535b by the guide plate 535c of the insert 535 And enters the communication hole 21 of the gas discharge portion 20 located at the lower portion of the bottom portion 535a through the opening 535a` formed in the bottom portion 535a at the lower end side of the column 535b do.

Meanwhile, FIG. 15 shows a battery cover according to another embodiment of the present invention. The battery cover according to the present embodiment includes an auxiliary discharge portion 60 extending along the gas discharge portion 20 and spaced apart from the gas discharge portion 20 by a predetermined distance, And the gas discharge unit 20 are connected to each other. In this embodiment, the gas inlet 30 is formed in the auxiliary outlet 60. Alternatively, the gas inlet 30 may be formed in the gas outlet 20.

The auxiliary discharge portion 60 has a passage corresponding to the gas discharge portion 20 formed therein and extends toward the longitudinal direction of the main body 10 and is formed at a position corresponding to the center of the length of the main body 10 And communicates with the gas discharge portion 20 by the communicating portion 70.

The communicating part 70 has a communicating space formed therein so that the gas introduced into the gas introducing part 30 through the gas introducing part 30 can be introduced into the gas discharging part 20 from the center of the length, And the passage of the gas discharge portion 20 are communicated with each other. The communication part 70 includes a lid having a structure similar to the gas inflow part 30 so as to close the communication space.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. You will understand that an example is possible. Therefore, the scope of the true technical protection of the present invention should be determined by the technical idea of the appended claims.

1: Cover 2: Case
10: main body 13: partition wall
20: gas discharge part 21: communication hole
30: gas inlet 31: body
31c: bypass hole 34: cover
40: blocking portion 41: body
45: a shielding film 50:
51: filter housing 55: explosion-proof filter
60: auxiliary discharge portion 70:

Claims (6)

A body formed to be capable of opening and closing an upper portion of a case filled with an electrolyte;
A gas discharge unit provided on a bottom surface of the main body to discharge gas generated inside the case to the outside of the case;
And a gas inflow part provided in the gas discharging part to allow gas generated inside the case to flow into the gas discharging part at a designated position. The method according to claim 1,
The gas inlet
A body having a predetermined length extending from the gas discharging portion and having an upper end opened and a space communicating with the gas discharging portion on an inner side;
An inner wall formed in the space part and guiding a gas flowing into the space part to the gas discharge part,
And a cover rotatably coupled to an upper portion of the body to open and close an upper portion of the body and to have openings on both sides of the case so that gas can pass from the case to the space. 3. The method of claim 2,
The inner wall has a central inner wall formed to partition the space part into a first space part and a second space part respectively in the left and right direction and a gas introduced into the first space part through an opening provided at one side of the lid, So that the gas introduced into the second space can be moved to the gas discharging part along the second inflow path through the opening provided in the other side of the lid. And a right inner wall guiding,
Wherein the gas discharging portion is formed with a communication hole for communicating the space portion and the gas discharging portion in an area corresponding to an end point of the first inflow path and the second inflow path, respectively. 4. The method according to any one of claims 2 to 3,
Wherein a bypass hole is formed at one side of the body for introducing gas in the case into the space when the opening of the lid is closed by the electrolyte filled in the case. The method according to claim 1,
And a blocking portion inserted into the gas discharging portion to allow gas flowing into the gas discharging portion through the gas inlet portion to pass therethrough and to block leakage of the electrolyte inside the case. 6. The method of claim 5,
The blocking portion
A tubular body having an outer diameter corresponding to an inner diameter of the gas discharging portion, a hollow portion formed in the hollow portion, and a lower portion opened,
And a plurality of barrier membranes coupled to the interior of the body to form a staggered or zigzag structure in the body so as to interfere with the electrolyte flowing along the interior of the body when the electrolyte enters the hollow. .

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