KR20140021128A - Battery case with anti-vibration structure - Google Patents

Abstract

The present invention relates to a battery case with an anti-vibration structure. More particularly, in the battery case, the bottom of a battery case is blocked and hot-melt is sprayed between the case and an electrode plate to block the bottom of the case in order to form an anti-vibration structure and fixate the electrode plate such that the battery case has an anti-vibration structure to protect the inside of the case from external impacts or vibrations.

Description

Battery case with vibration resistance structure {Battery case with anti-vibration structure}

The present invention relates to a battery case having a vibration-resistant structure, and more particularly, to block the bottom of the battery case, and to spray a hot-melt between the case and the electrode plate to block the bottom surface of the case The present invention relates to a battery case having a vibration resistant structure capable of securing a vibrating structure and at the same time fixing the electrode plate to protect the interior from external shock or vibration.

In general, lead-acid batteries for automobiles contain lead-based electrodes and dilute sulfuric acid electrolyte, and polypropylene rolled steel and cover are used. Of these, the precursor serves to store the electrode plate 50 and the electrolyte.

Such a lead-acid battery for a vehicle includes a bottom of a battery case to prevent problems such as damage to an inner pole plate and leakage of electrolyte due to an impact applied to the vehicle when the mounted vehicle is driven on a road where the driving environment is poor, such as an off-road. A technique for mitigating the impact on the plate by installing a separate jig on the face has been proposed.

In the conventional vibration resistant structure for storage batteries, a method of fixing the electrode plate by applying an adhesive means, which is a liquid resin, to the bottom surface has been proposed. Such a vibration resistance structure for a conventional battery has a lot of problems because the amount of the adhesive means must be applied to the entire bottom surface.

In addition, the conventional vibration-resistant vibration structure for a battery has a problem in that damage to the electrode plate and leakage of the electrolyte are generated because shock or vibration transmitted through the bottom surface is transmitted to the electrode plate because the electrode plate is adhesively fixed to the bottom surface.

The present invention has been made to solve the conventional problems as described above, the object of the present invention is to block the bottom surface of the battery case to mitigate the impact or vibration applied from the outside, it is possible to reduce the amount of use of the adhesive means It is to provide a battery case having a vibration resistant structure.

The present invention includes the following embodiments in order to achieve the above object.

A first embodiment of the present invention, in the case for a battery having a vibration-resistant structure, one or more cases in which the pole plate is seated by the wall surface standing up; An anti-vibration block comprising one or more blocks protruding upward from the bottom of the case to have different heights to support the bottom of the electrode plate; And adhesion means for adhesively fixing the pole plate and the vibration resistant block, wherein the vibration resistant block is formed integrally with the support block and spaced apart from the bottom surface of the pole plate to support the lower surface of the pole plate. It includes a guide block forming a.

In the second embodiment of the present invention, the bonding means is applied to the upper surface of the guide block is filled in the empty space between the lower surface of the electrode plate and the upper surface of the guide block.

In a third embodiment of the present invention, the battery case having the vibration-resistant structure includes an injection groove extending downward from the wall surface of the case and in communication with the guide block, the bonding means is the injection groove through the injection groove It is characterized in that it is applied to the upper surface of the guide block.

In the fourth embodiment of the present invention, the guide block includes a first guide block and a second guide block which are formed extending from one side to one side with respect to the support block and coated with the adhesive means injected through the injection groove. do.

The fifth embodiment of the present invention further includes a transfer groove through which the adhesive means is transferred by being cut laterally and communicating between the first guide block and the second guide block.

In the sixth embodiment of the present invention, the injection groove is preferably connected to one selected from the first guide block and the second guide block.

In the seventh embodiment of the present invention, the battery case having the vibration-resistant structure further includes a display unit for displaying the position of the guide block in the intaglio or embossed letters, symbols and colors at the upper end of the case wall do.

The present invention supports the electrode plate using blocks having different heights on the bottom surface of the battery case as described above, and limits the area in which the adhesive means flows, thereby reducing the amount of adhesive means, thereby reducing material costs. In addition, the shock and vibration applied from the outside can be mitigated through the block structure, thereby preventing damage to the electrode plate.

1 is a perspective view showing a battery case having a vibration resistant structure according to the present invention,
2 is a side cross-sectional view of a battery case having a vibration resistant structure according to the present invention;
3 is a plan view of a battery case having a vibration resistant structure according to the present invention;
4 is an enlarged perspective view of a part of a battery case having a vibration resistant structure according to the present invention;
5 is a perspective view showing another embodiment of a battery case having a vibration resistant structure according to the present invention.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of a battery case having a vibration-resistant structure according to the present invention will be described in detail.

1 is a perspective view showing a battery case having a vibration resistant structure according to the present invention, Figure 2 is a side cross-sectional view of a battery case having a vibration resistant structure according to the present invention, Figure 3 is a vibration resistant structure according to the present invention 4 is a perspective view showing an enlarged portion of a bottom surface of a battery case having a vibration resistant structure according to the present invention.

1 to 4, a case 10 for a battery having a vibration resistant structure according to the present invention includes a pole plate 50, front and rear left and right sides 11 and 12, and a bottom surface 13. ), One or more partition walls 40 for dividing the inner space of the case 10 into one or more, and bottom heights 13 of the space divided into one or more by the partition walls 40 and have different heights. It includes a vibration-resistant block 20 for supporting the pole plate 50, and the adhesive means 30 for bonding and fixing the vibration-resistant block 20 and the pole plate 50.

The case 10 forms an inner space by wall surfaces 11 and 12 forming front, rear, right and left sides. Here, the inner space of the case is divided into one or more spaces by one or more partition walls 40 formed of upright wall surfaces fixed to both sides.

One or more pole plates 50 are fixed inside the one or more spaces of the case 10. Here, the pole plate 50 is a pole plate assembly in which one or more pole plates are connected to each other so as to be electrically energized, and are collectively described as pole plates for convenience of description.

The case 10 is formed with injection grooves 111, 121, 121 ′ through which the adhesive means 30 are injected from at least one of the front and rear surfaces 11 and the left and right side surfaces 12. The injection grooves 111, 121, 121 ′ extend downward from at least one of the front and rear surfaces 11 and both sides 12 of the case 10 to vibrate the bonding means 30. Guide to block 20. Here, the injection grooves 111, 121, 121 ′ are formed at least one space for each of the spaces divided by the partition 40, and more preferably, the guide block 21 of the vibration resistant block 20 described later. It is preferable to install the same number.

The vibration-resistant block 20 may be fixed to different heights from the bottom surface 13 of the case 10 to support the lower portion of the pole plate 50 to mitigate external shocks. To this end, the vibration-proof block 20 is formed to have a lower height than the upper surface of the support block 22 and the upper surface of the support block 22, the support plate 22 is formed between the lower surface and the upper surface of the electrode plate. It comprises a guide block 21 to form a space to form a space in which the bonding means 30 is filled.

The guide block 21 extends in the same direction as the support block 22 to an upper surface having a lower height than the support block 22 so as to communicate with the injection grooves 111, 121, 121 ′. Therefore, the guide block 21 is filled with the adhesive means 30 is injected into the upper surface through the injection grooves (111, 121, 121 ').

The bonding means 30 is introduced into the space between the guide block 21 and the lower surface of the electrode plate 50 and cured to bond the electrode plate 50 and the support block 22 to each other. Here, the adhesive means 30 is injected through the injection device having a pointed injection hole with a liquid plastic resin. And the adhesive means 30 is preferably applied to the product curable within 1 to 3 minutes after being applied. For example, since the adhesive means 30 applies a hot-melt, which is a generally known product, a detailed description thereof will be omitted.

The vibration-resistant block 20 extends in the same direction from one side of the support block 22 and the support block 22 on which the lower surface of the pole plate 40 is seated on an upper surface thereof, and the adhesion means 30 is filled in the guide. Block 21.

The support block has an upper surface protruding upward, and both ends of the support block extend on both side wall surfaces of the case.

In addition, the guide block 21 forms an upper surface to which the adhesive means 30 is applied and extends in the same direction as the support block 21. Here, the guide block 21 and the support block 22 are integrally formed, and each of the guide blocks 21 and 21 'is integrally formed or two supports are formed at both sides with the support block 22 therebetween. It is also possible that the three guide blocks 21, 21 ′, 21 ″ are integrally formed between the blocks 22, 22 ′ with the support blocks 22, 22 ′ therebetween.

Here, the guide block 21 may be connected to each of the injection grooves 111, 121, and 121 ′ or only one or more selected.

For example, when the injection groove 111 is formed on one side of the front surface of the case 10, the first guide block 21 extends laterally from the front surface of the case 10 to the injection groove 111. Communicating. In addition, the first support block 21 extends in the same direction on one side of the first guide block 21. Therefore, the adhesive means 30 injected from the injection groove 111 of the front surface 11 is introduced into the empty space between the lower surface of the electrode plate 50 and the upper surface of the first guide block 21 to the electrode plate 50. Can be fixed.

In addition, the second guide block 21 is positioned on the other side of the first support block 22, and the second support block 22 is extended to be in close contact with the other side of the second guide block 21. The other side of the second support block 22 is located on the bottom surface 13 in which the partition wall 40 is formed instead of a separate block structure.

In addition, the second guide block 21 communicates with the second injection groove 121 formed on one side of the case 10. In conclusion, the first guide block 21 guides the adhesive means 30 injected by the first injection groove 111 located on the front surface, and the second guide block 21 passes through the one side surface. The adhesive means 30 injected through the second injection groove 121 to be injected is filled.

In the above-described embodiment, when the width of the case 10 and the width of the electrode plate 50 are formed to be in close contact with each other, it is preferable to form the injection grooves 111, 121, and 121 ′ as described above. It is also possible to inject the adhesive means 30 between the pole plate 50 and the wall surface 12 of the case 10.

At this time, the designer is engraved or embossed as a symbol at the top of the wall (11, 12) consisting of the front and rear, right and left sides of the case 10 instead of the injection groove (111, 121, 121 ') , A display unit (not shown) capable of displaying the positions of the guide blocks 21, 21 ′, 21 ″ in any one of numbers or colors can be installed for convenience of work.

Wherein the adhesive means 30 is a device that includes a syringe-type injection port as the end of the injection point is sharply extended to check the position of the guide block 21 through the display portion to the pole plate 50 and the case 10 After the injection hole is inserted between the gaps between the sides, the adhesive means 30 may be injected.

Such a modification is one of various applications falling within the scope of the technical idea of the present invention, and this may be selectively applied according to the intention of the designer and the operator.

The present invention includes the configuration as described above, the following will be described in detail the operation of the present invention including the configuration as described above.

First, a worker connects and seats the electrode plate 50 so as to be electrically energized in each space divided by one or more partition walls 40 in the case 10. At this time, the pole plate 50 is seated on the upper surface of the support block 22, is spaced apart from the upper surface of the guide block 21 by a predetermined interval.

Then, when all of the pole plate 50 is seated in the space in which the one or more are divided, the injection hole of the injection device of the bonding means 30, the injection groove (111, 121, 121 ') or the pole plate 50 and the case 10 Inject into the gaps formed between the side or front and rear surfaces.

In the case where the injection grooves 111, 121, 121 ′ are formed as described above, the injection hole is placed on the upper end of the injection grooves 111, 121, 121 ′ and then the adhesive means 30 is injected. Alternatively, when the worker injects the adhesive means 30 into the gap between the pole plate 50 and the front, rear, left and right sides instead of the injection grooves 111, 121 and 121 ′, the operator is formed on the top of each wall surface of the case 10. Check the display unit (not shown) and insert the injection hole.

Then, when the worker injects the adhesive means 30 through the injection hole, the injected adhesive means 30 fills the entire empty space formed between the guide block 21 and the lower surface of the electrode plate 50. Here, the adhesive means 30 is omitted for the description of the material and the curing process to apply a known product in general.

Therefore, the operator fills the adhesive means 30 to each of the guide blocks 21 through the gaps between the respective injection grooves 111, 121, 121 ′ or the pole plate 50 and the wall surface. When curing of the bonding means 30 is completed, the case 10 may be transferred to the next process.

In addition, the present invention is a configuration of one embodiment for injecting the adhesive means 30 to each of the guide block 21 through the injection groove (111, 121, 121 ') and the display unit (not shown) as described above As described above, another embodiment will be described with reference to FIG. 5.

5 is a perspective view showing another embodiment of a battery case 10 having a vibration resistant structure according to the present invention.

Referring to FIG. 5, another embodiment of the present invention may form a passage through which the adhesive means 30 is transferred between the first guide block 21 and the second guide block 21. That is, as shown in another embodiment of the present invention extends in the horizontal direction to the first support block 22 protruding upward between the first guide block 21 and the second guide block 21, the first guide block And a transmission groove 23 through which 21 and the second guide block 21 communicate.

The transfer groove 23 is attached to any one of the first guide block 21 and the second guide block 21 as the communication between the first guide block 21 and the second guide block 21. When 30 is injected, it can be delivered to the other side to shorten the process of inserting one or more injection means for injection means 30 for each guide block 21.

Here, the adhesive means 30 is a liquid plastic resin, the time of completely curing after the injection is about 2 to 5 minutes. Therefore, it is not desirable for the operator to fill the adhesive means in too many guide blocks 21 in one injection, and to fill the two or three guide blocks 21 in one injection in consideration of the length of the guide block. desirable.

The present invention is provided with one or more vibration resistant blocks 20 having different heights from each other on the bottom surface 13 of the case 10 as described above to separately support the adhesive area and the support area by the adhesive means 30. It is possible to save the amount of use of the adhesive means 30 and at the same time improve the vibration resistance to mitigate the shock and vibration applied from the bottom surface (13).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

10: case 11: front
12: side 13: bottom surface
20: Vibration resistant block 21, 21 ': guide block
22, 22 ': support block 23: transmission groove
30: bonding means 40: partition wall
111, 121, 121 ': injection groove

Claims (7)

A case in which at least one pole plate is seated by an upstanding wall and forms a space;
An anti-vibration block comprising one or more blocks protruding upward from the bottom of the case to have different heights to support the bottom of the electrode plate; And
And adhesive means for adhesively fixing the pole plate and the vibration resistant block.
The vibration-resistant block is a battery case having a vibration-resistant structure including a support block for supporting a lower surface of the pole plate and a guide block formed integrally with the support block to form a space spaced apart from the lower surface of the pole plate on an upper surface. . The method of claim 1, wherein the bonding means
The battery case having a vibration-resistant structure is applied to the upper surface of the guide block is filled in the empty space between the lower surface of the electrode plate and the upper surface of the guide block. The battery case according to claim 1 or 2, wherein the battery case has the vibration resistant structure.
An injection groove extending downward from the wall of the case and communicating with the guide block;
The adhesive means is a battery case having a vibration-resistant structure, characterized in that applied to the upper surface of the guide block through the injection groove. The method of claim 3, wherein the guide block
The battery case having a vibration-resistant structure is formed extending in one direction from both sides with respect to the support block is formed integrally with the first guide block and the second guide block to which the adhesive means is applied. The battery case according to claim 4, wherein the battery case has a vibration resistant structure.
The battery case having a vibration-resistant structure further comprises a transmission groove which is cut laterally from the support block and communicates between the first guide block and the second guide block to which the adhesive means is transferred. The method of claim 5, wherein the injection groove
Case for a battery having a vibration-resistant structure, characterized in that connected to at least one selected from the first guide block and the second guide block. According to claim 1, wherein the battery case having the vibration-resistant structure
The battery case having a vibration-resistant structure further comprises a display unit for displaying the position of the guide block in the intaglio or embossed letters, symbols and colors at the top of the case wall.

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