KR100911520B1 - Storage device of battery module - Google Patents

Abstract

The present invention changes the structure of the housing for accommodating the battery module in a stacked manner to simplify the mold required for the manufacture of the storage device of the battery module and to reduce the cost, and to shorten the process required when assembling the battery module. Its purpose is to help.

In order to achieve the above object, the present invention provides a plurality of holding members 100 are laminated and bonded in a layer; Dividing the stacking surface 110 between the holding member 100 to form a single space, the receiving portion 200 is arranged in a plurality of rows along the stacking surface 110; A shock absorbing member 300 mounted to the accommodating part 200; It is characterized in that it comprises a plurality of battery modules 400 which are surrounded by the buffer member 300 and installed in the accommodating part 200 and are electrically connected to each other.

Description

Storage device of battery module

1 is a perspective view showing a storage device of a conventional battery module.

2 is a cross-sectional view showing a coupling portion between the inner / outer walls and the buffer member in FIG.

3 is a perspective view showing a storage device of a battery module with a holding member according to the first embodiment of the present invention.

4 is an exploded perspective view of FIG. 3.

5 is a perspective view illustrating a storage device of a battery module including a mounting plate and a cover plate.

Figure 6 is an exploded perspective view showing a storage device of a battery module with a holding member according to a second embodiment of the present invention.

7 is a view showing an installation state of a bus bar plate for electrical connection between battery modules.

8 to 10 is a view showing a fastening state of the holding member laminated in a layer.

11 is a view showing a bonding state between holding members stacked in layers.

12 is a view showing the configuration of a buffer member according to a first embodiment of the present invention.

13 is a view showing the configuration of a buffer member according to a second embodiment of the present invention.

14 is a view showing the configuration of a buffer member according to a third embodiment of the present invention.

15 is a view showing the configuration of a buffer member according to a fourth embodiment of the present invention.

16 is a view showing the configuration of a buffer member according to a fifth embodiment of the present invention.

17 is a view showing the configuration of a buffer member according to a sixth embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a storage device for a battery module, which can simplify the manufacturing process of a storage holding part for storing the battery module and shorten the assembly process.

In general, battery modules used in a hybrid vehicle are arranged to have a constant direction in a plurality of rows in a box-shaped storage device, and each battery module is stored in a mechanically connected state while being electrically connected to each other. do.

That is, the storage device of the conventional battery module, as shown in FIG. And a through part 5 formed in a plurality of rows and columns at respective corresponding positions on the outer wall 1a and the inner wall 1b to form a circular empty space for inserting and supporting the battery module 3. ).

In addition, the through part 5 is provided with a buffer member 7 for buffering the battery module 3 is installed, the buffer member 7 is the outer wall (1a) and the inner wall (1b) It is made of a structure having a cylindrical shape (7a) integrally inserted into the through portion 5 while having the same shape for the).

In addition, the housing 1 is integrally formed with a mounting bracket 9 for installing the storage device of the battery module, and the mounting bracket 9 is integrally formed when the housing 1 is molded.

Therefore, the battery module 3 accommodated in the housing 1 is inserted into and supported in the cylindrical protrusion 7a of the buffer member 7 coupled to the through part 5.

However, the storage device of the conventional battery module having the above structure has the following problems.

First, since the storage device of the conventional battery module integrally forms the outer wall 1a, the inner wall 1b, and the penetrating portion 5, a mold having a complicated shape must be manufactured at the time of manufacture, thereby increasing the manufacturing cost of the mold and There has been a problem of delay in manufacturing and increase in labor costs as the mold repair and the mold production period become longer.

In addition, when the cushioning member 7 is installed, there is a problem that the time required for the fitting process of the cylindrical protrusions 7a to the plurality of through parts 5 formed on the outer wall 1a and the inner wall 1b becomes excessive. there was.

In addition, when assembling the battery module 3, the battery module 3 must be inserted into the plurality of cylindrical protrusions 7a, one by one, there is a problem that the time and effort required for assembly are excessive.

Accordingly, the present invention has been made in view of the above, and by changing the structure of the housing for accommodating the battery module into a stacked type, it is possible to simplify the mold and reduce the cost required for the manufacture of the storage module of the battery module. In order to shorten the process required for assembling the battery module, the purpose is to reduce the number of steps.

The present invention for achieving the above object, and a plurality of holding members that are laminated and bonded in a layer;

A storage portion which bisects the laminated surfaces between the holding members to form a single space, and the space is arranged in a plurality of rows along the laminated surface;

A shock absorbing member mounted on the receiving part;

It is characterized in that it comprises a plurality of battery modules which are surrounded by the buffer member and installed in the receiving portion and electrically connected to each other.

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

As shown in FIGS. 3 and 4, the present invention includes a plurality of holding members 100 arranged to be stacked in a layer of upper and lower layers and integrally coupled to each other, and between the holding members 100. Dividing the stacking surface 110 up and down to form a single space, the storage unit 200, the number of the space is arranged in a plurality of rows along the stacking surface 110, the number Shock absorbing buffer member 300 of the resins mounted on the payment part 200 and a plurality of battery modules 400 that are surrounded by the buffer member 300 is installed in the accommodating portion 200 and are electrically connected to each other. It is made, including.

The holding member 100 according to the first embodiment of the present invention consists of an upper / lower divided body 120 and an intermediate divided body 140, and the upper / lower divided body 120 includes the battery module ( A pair of first horizontal walls 122 formed horizontally along an arrangement direction of 400 and a direction intersecting with an arrangement direction of the battery module 400 at both left and right ends of the first horizontal wall 122 The first outer wall 124 and the first inner wall 124 of the first inner wall 124 are formed integrally spaced apart at equal intervals.

The intermediate split body 140 has a second horizontal wall 142 formed horizontally along the placement direction of the battery module 400 and the battery module 400 at both left and right ends of the second horizontal wall 142. A pair of second outer walls formed at positions spaced apart from each other along a direction intersecting with the arrangement direction of the upper and lower positions and respectively matched and stacked with respect to the first outer walls 124 of the upper and lower divided bodies 120. 144 and the second outer wall 144 are spaced at equal intervals from each other and are stacked to match the first inner wall 126 of the upper and lower divided bodies 120, respectively. The second inner wall 146 formed therein is integrally provided.

Here, fastening holes 128 and 148 are formed at the edges of the upper and lower split bodies 120 and the middle split bodies 140 to form layers through the bolts B and the nuts N.

In this case, the accommodating part 200 includes a stacking surface 110 between the upper and lower split bodies 120 and the middle split body 140, and a stacking surface 110 between the middle split body 140. Along the through hole formed in a plurality of rows.

As shown in FIG. 5, a mounting plate 500 is seated on a bottom surface of the lower split body 120, and the mounting plate 500 covers an outside of the upper split body 120. ) Is combined.

As a result, the holding member 100 laminated in the layer can be maintained in a state that is firmly stacked by the mounting plate 500 and the cover plate 510.

In this case, the bolt B is sequentially passed through the cover plate 510, the fastening holes 128 and 148, and the mounting plate 500 to be fastened to the nut N.

As shown in FIG. 6, the holding member 100 according to the second embodiment of the present invention is formed as a bar of a rectangular shape, and along a direction intersecting with an arrangement direction of the battery module 400. It is composed of a plurality of dividers 160 are arranged at a predetermined distance and stacked in a layer to be integrally combined.

Here, a fastening hole 162 is formed in the edge portion of the partition 160 to form a layer via the bolt B and the nut N.

In this case, the accommodating part 200 is formed of a through hole formed in a plurality of rows along the stacking surface 110 between the partitions 160 stacked in the layered manner.

That is, in the first and second embodiments of the present invention, the accommodating part 200 is formed in the same shape as that of the battery module 400. For example, when the battery module 400 is set as a cylindrical body, the accommodating part 200 is set as grooves each formed in a semicircular shape in the stacking surface 110 between the holding members 100, and is coupled to the combination of these grooves. As a result, the accommodating part 200 has a circular shape in cross section.

As shown in FIG. 7, the stacking surface 110 between the accommodating parts 200 located at the outermost side of the holding member 100 among the accommodating parts 200 penetrates between adjacent accommodating parts 200. A groove H is formed, and the groove H is mounted with a busbar plate 410 that electrically connects the battery modules 400 installed in the adjacent housing 200. Accordingly, the plurality of battery modules 400 mounted on the accommodating part 200 may be electrically connected to each other via the bus bar plate 410.

As shown in FIG. 8, when the bolt B sequentially passes through the plurality of holding members 100 stacked in layers, and then is fastened to the nut N, the bolt B is fastened when the bolt B is fastened. Torsional deformation may be generated at the shaft portion of the bolt B by the torque transmitted to (B). In this case, the torsional deformation generated at the shaft portion of the bolt B may be the bolt (B) and the nut (N). Since the clamping force between them is reduced, it is preferable to set the length of the said bolt B to the minimum.

For this purpose, as shown in FIGS. 9 and 10, it is preferable to set the fastening length by the bolt B to be shorter in the plurality of holding members 100 stacked in layers.

That is, as shown in Figure 9, the length of the holding member (101, 102) located in the uppermost layer and the lowermost layer of the plurality of holding member 100 stacked in the layer than the length of the holding member 103 located in the intermediate layer Both ends of the holding member 102, which is set long and positioned at the lowermost layer, are bent to surround both ends of the holding member 103 positioned at the intermediate layer, and both ends of the holding member 101 positioned at the uppermost layer. The side bottom portion is contacted and engaged.

In this case, the fastening holes 128, 148, and 162 for fastening the bolts B may be limited to the front end portions of the holding members 101 and 102 positioned on the uppermost layer and the lowermost layer of the plurality of holding members 100.

In addition, as shown in FIG. 10, the lengths of the holding members 111, 112, and 113 positioned on the uppermost layer, the lowermost layer, and the middle layer among the plurality of holding members 100 stacked in the layer are between the uppermost layer, the middle layer, and the lower layer and the middle layer. It is set longer than the length of the intermediate layer holding member 114 respectively positioned between,

Both end portions of the holding member 113 positioned in the middle layer are bent to surround both ends of the middle layer holding member 114, and bottom portions of both end portions of the holding members 111 and 112 positioned at the top and bottom layers. Each contact is combined.

In this case, the fastening holes 128, 148, and 162 for fastening the bolts B may be formed to be limited to both end portions of the holding members 111, 112, and 113 positioned on the uppermost layer, the lowest layer, and the middle layer of the plurality of holding members 100. .

Therefore, when fastening by using the bolt (B) and the nut (N) in a state in which a plurality of holding members 100 are laminated in a layer using the structure shown in Figs. The fastening distance of the can be greatly shortened.

In addition, when the length of the bolt (B) for fastening the plurality of holding members 100 is set to be shorter, the torque applied to the bolt (B) when the bolt (B) is fastened to the bolt (B) Since it is possible to act solely on the fastening of, it is possible to prevent the fall of the fastening force due to the torsional deformation generated in the shaft portion of the bolt (B).

As shown in FIG. 11, the recessed portions 100a and the convex portions 100b for fitting are respectively formed on positions of the stacking surfaces 110 between the holding members 100. That is, the recess 100a is formed in one of the two holding members 100 stacked, and the convex part 100b is formed in the other.

In this case, the cross-sectional shape of the recess portion 100a and the convex portion 100b may be set in various forms such as a square shape, a wedge shape, and an arc shape as shown in FIG. 11.

Accordingly, the plurality of holding members 100 stacked in a layer may maintain the bonding state more firmly until the time point before the screwing operation is performed through the fitting coupling between the recessed portion 100a and the convex portion 100b. Will be.

On the other hand, the buffer member 300 of the shock absorbing material such as rubber is installed and fixed over the entire circumference of the accommodating part 200, the buffer member 300 is the accommodating part 200 It is to perform the function of shock mitigation for the battery module 400 that is seated on.

To this end, the buffer member 300 is installed in the accommodating part 200 in various forms. First, as shown in FIG. 12, the buffer member 300 according to the first embodiment has the laminated surface 110. ) And a first buffer portion 302 having a plurality of concave curved portions 302a corresponding to the accommodating portion 200 and bent at approximately 90 ° at both ends of the first buffer portion 302. And integrally include a second buffer unit 304 that surrounds both sides of the stacking surface 110.

In addition, as shown in FIG. 13, the buffer member 300 according to the second embodiment includes a third buffer portion 306 formed concave to cover the accommodating portion 200 individually, and the third buffer portion. It is made of a structure integrally provided with the fourth buffer portion 308 is bent at approximately 90 degrees at both ends of the 306 to surround both sides of the laminated surface (110).

In addition, the buffer member 300 according to the third embodiment is, as shown in Figure 14, the fifth buffer portion 310 formed to be concave to cover the accommodating portion 200, and the fifth buffer portion Protruding to the rear surface of the 310 is made of a structure having a first fitting pin 312 integrally fitted in the first insertion groove 210 formed in the receiving portion 200.

In addition, the shock absorbing member 300 according to the fourth embodiment has a concave curved portion 314a corresponding to the accommodating portion 200, as shown in FIG. 15, and is adjacent to the accommodating portion 200. A sixth buffer portion 314 covering the stack surface 110 and a second protrusion protruding from both ends of the sixth buffer portion 314 to be inserted into the second insertion groove 220 formed in the stack surface 110. It is made of a structure having a fitting pin 316 integrally.

In addition, the buffer member 300 according to the fifth embodiment is coupled to the outer periphery of the battery module 400, as shown in Figure 16, the first groove recessed along the longitudinal direction of the housing 200 It consists of an O-ring 318 fitted to (230).

In addition, the shock absorbing member 300 according to the sixth embodiment includes the accommodating part 200 and is recessed along the stacking surface 110 adjacent to the accommodating part 200, as shown in FIG. 17. A belt-shaped member 320 having a curved portion 320a accommodated in the second groove 240, and a third insertion groove 250 formed in the second groove 240 by protruding to the rear surface of the belt-shaped member 320. It is made of a structure integrally provided with a third fitting pin 322 to be fitted therein.

In this case, the second groove 240 has a polygonal cross section, and the cross section of the strip-shaped member 320 is circular or polygonal, and the protruding height of the strip-shaped member 320 is the second groove 240. It is preferably set to a degree slightly exceeding.

Therefore, the assembly of the storage device of the battery module of the above structure is made through the following process.

First, the holding member 100 is placed on an upper portion of the mounting plate 500, and then each of the buffer members 300 is individually installed in the receiving parts 200 formed in the holding member 100. do. Subsequently, the battery module 400 is separately mounted to the buffer member 300.

When this process is repeated a plurality of times, the holding member 100 can be stacked in a plurality of layers, and finally, the cover plate 510 is assembled, and then bolts (through fastening holes 128, 148, 162) are provided. B) is inserted and the bolt B is fastened as a nut (not shown) at the bottom of the mounting plate 500.

As described above, according to the storage device of the battery module according to the present invention, since the storage device for storing a plurality of battery modules is laminated in a layer structure, the mold required for the production of the storage device can be simplified. Accordingly, the cost of repairing and manufacturing the mold can be reduced.

In addition, since the storage module of the battery module is stacked in a layer structure, it is possible to reduce the time required when assembling a plurality of battery modules. Since the workability can be greatly improved, it is possible to greatly reduce the time required for assembly.

In addition, even when the buffer member is installed in the storage device of the battery module, it is only necessary to simply put the buffer member on each holding member arranged in a layer, thereby reducing the time required for assembling the buffer member as compared to the conventional work. Sex can be greatly improved.

Claims (15)

A first horizontal wall formed along a direction in which the battery module is disposed and spaced apart from each other between the first outer wall and the first outer wall formed in a direction crossing the direction in which the battery module is disposed at both left and right ends of the first horizontal wall; An upper / lower split body integrally provided with a first inner wall, a second horizontal wall formed along an arrangement direction of the battery module, and the first outer wall of the upper / lower divided body at both left and right ends of the second horizontal wall; And an intermediate split body integrally provided with a second inner wall formed at a position corresponding to the second inner wall and a second inner wall formed at a position coincident with the first inner wall of the upper / lower divided body between the second outer wall. A holding member having a fastening hole formed in the laminated surface between the lower divided body and the intermediate divided body; The laminated surface between the upper and lower divided bodies and the intermediate divided body and the laminated surface between the intermediate divided bodies are bisected to form a single space, and the space is formed through a plurality of rows of through holes along the laminated surface. Receiving portion consisting of; Storage device of a battery module comprising a shock absorbing member mounted to the receiving portion to surround the battery module. delete delete Holds having a plurality of partitions stacked in a layer and integrally coupled in a state in a state arranged at a predetermined separation distance along the direction crossing the battery module arrangement direction, and a fastening hole formed in the laminated surface between the partitions A support member; Dividing the laminated surface between the divided bodies to form a single space, the storage portion consisting of through-holes arranged in a plurality of rows along the laminated surface; Storage device of a battery module comprising a shock absorbing member mounted to the receiving portion to surround the battery module. delete The method according to claim 1 or 4, Grooves penetrating between adjacent housing portions are formed in the stacked surface between the housing portions located at the outermost side of the holding member, and the groove portions electrically connect the battery modules installed in the adjacent storage portions. Storage device for a battery module, characterized in that the bus bar plate is mounted. The method according to claim 6, The length of the holding member positioned on the uppermost layer and the lowermost layer among the plurality of holding members stacked in the layer is set longer than the length of the holding member positioned on the intermediate layer, and both front ends of the holding member positioned on the lower layer are the intermediate layer. Storage device of a battery module, characterized in that bent to surround both ends of the holding member located in the coupled to the bottom end of both ends of the holding member located on the top layer. The method according to claim 6, Among the plurality of holding members stacked in layers, the lengths of the holding members positioned on the top layer, the bottom layer, and the middle layer are set to be longer than the length of the middle layer holding member, respectively, located between the top layer and the middle layer and between the bottom layer and the middle layer. The battery is characterized in that the front end of the both ends of the holding member located in the middle layer is bent to surround both ends of the holding member of the intermediate layer is coupled to the bottom end of both ends of the holding member located in the uppermost layer and the lowest layer, respectively. Module storage. The method according to claim 7, Storage device for a battery module, characterized in that the laminated surface between the holding member is formed with recesses and convex portions for fitting to each other in a corresponding position. The method according to claim 9, The buffer member includes a first buffer portion having a concave curved portion corresponding to the storage portion to cover the stack surface, and a second buffer portion bent at both ends of the first buffer portion to surround both sides of the stack surface. Storage device for a battery module, characterized in that equipped with. The method according to claim 9, The buffer member is a storage device of a battery module, characterized in that having a third buffer portion formed to be concave to cover the receiving portion, and the fourth buffer portion integrally bent at both ends of the third buffer portion surrounding both sides of the laminated surface. . The method according to claim 9, The shock absorbing member is integrally provided with a fifth buffer part formed to be concave so as to cover the accommodating part, and a first fitting pin that protrudes into a rear surface of the fifth shock absorbing part and fits into a first insertion groove formed in the accommodating part. Storage device for the battery module. The method according to claim 9, The shock absorbing member has a concave curved portion corresponding to the accommodating part, and includes a sixth shock absorbing part covering the stacking surface adjacent to the accommodating part, and a second insertion projecting to the rear surface of the sixth buffer part. Storage device for a battery module, characterized in that it is provided with a second fitting pin fitted in the groove integrally. The method according to claim 9, The shock absorbing member is coupled to the outer circumference of the battery module storage device of the battery module, characterized in that made of an O-ring fitted in the first groove recessed along the longitudinal direction of the receiving portion. The method according to claim 9, The buffer member includes a belt-shaped member including the accommodating portion and a curved portion formed in a second groove recessed along the stacking surface adjacent to the accommodating portion, and protruding from the rear surface of the band-shaped member to be formed in the second groove. Storage device for a battery module, characterized in that provided with a third fitting pin that is fitted in the third insertion groove integrally.

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