JP6233110B2 - Battery module - Google Patents

Description

  The present invention relates to a battery module.

  Patent Document 1 describes a battery assembly. The battery assembly includes a plurality of single batteries arranged in a predetermined direction, a pair of holding plates disposed so as to sandwich the plurality of single batteries from both sides in a predetermined direction, and one holding plate to the other holding A plurality of rods extending to reach the plate. This battery assembly is modularized by connecting a pair of holding plates to each other via a rod so as to sandwich a plurality of single batteries.

JP-A-8-148187

  By the way, in the battery assembly described above, the single battery may expand with age deterioration, for example. In that case, as a result of an increase in load applied to a connecting member such as a rod that connects the holding plates so as to sandwich the single battery, the connecting member may be broken.

  This invention is made | formed in view of such a situation, and it aims at providing the battery module which can suppress the fracture | rupture of a connection member.

  In order to solve the above problems, a battery module according to the present invention includes a battery unit including a plurality of battery cells arranged in a predetermined direction, and one end and the other end of the battery unit in a predetermined direction. A pair of end members respectively disposed in the section, and a connecting member that connects the end members to each other so that the battery unit is sandwiched by the pair of end members, the end member facing the battery cell And a connecting region where the connecting member is disposed, and an intermediate region between the opposing region and the connecting region, the intermediate region being formed thinner than the average thickness of the opposing region in a predetermined direction It is characterized by including.

  In this battery module, end members are arranged at both ends of the battery unit in the arrangement direction of the battery cells. Then, the end members are connected to each other by the connecting member so that the battery unit is sandwiched between the pair of end members. In addition, the end member has a facing region facing the battery cells of the battery unit, a connecting region where the connecting member is disposed, and an intermediate region between them. The intermediate region includes a fragile portion that is thinner than the average thickness of the facing region facing the battery cell. Therefore, when the load applied to the connecting member increases with the expansion of the battery cell, the end member easily deforms in the direction in which the connecting regions of the pair of end members approach each other, starting from the weakened portion in the intermediate region. For this reason, the breakage of the connecting member can be suppressed by reducing the increase in the load applied to the connecting member.

  In the battery module according to the present invention, the end member includes a first member disposed on the battery unit, and a second member disposed on the battery unit and the first member and fastened to the first member. The connecting member connects the first members to each other, the facing region is a region facing the battery cell in the first member and the second member, and the connecting region is It is a region where the connecting member in one member is disposed, and the intermediate region may be a region between the opposing region and the connecting region in the first member. In this case, an opposing region that is thicker on average than the thickness of the weakened portion in the intermediate region can be easily configured by the first member and the second member. That is, formation of a weak part is facilitated.

  ADVANTAGE OF THE INVENTION According to this invention, the battery module which can suppress the fracture | rupture of a connection member can be provided.

It is a side view of the battery module concerning this embodiment. FIG. 2 is a partial cross-sectional view illustrating a structure of an end portion of the battery module illustrated in FIG. 1. It is a typical side view which shows a mode that the end member of the battery module shown by FIG. 1 deform | transforms. It is a fragmentary sectional view showing the modification of the battery module shown in FIG.

  Hereinafter, an embodiment of a battery module according to the present invention will be described in detail with reference to the drawings. In the description of the drawings, the same elements or corresponding elements are denoted by the same reference numerals, and redundant description is omitted.

  FIG. 1 is a side view of the battery module according to the present embodiment. FIG. 2 is a partial cross-sectional view showing a structure of an end portion of the battery module shown in FIG. As shown in FIGS. 1 and 2, the battery module 1 includes a battery unit 10, a pair of end members 20, and a plurality of connecting members 30.

  The battery unit 10 includes a plurality (here, seven) of battery cells 11 arranged along a predetermined direction and a plurality (here, seven) of heat transfer disposed between the battery cells 11 adjacent to each other. Plate 12. The battery cell 11 is a nonaqueous electrolyte secondary battery such as a lithium secondary battery.

  The end members 20 are disposed at one end 10a and the other end 10b of the battery unit 10 in the arrangement direction (predetermined direction) of the battery cells 11, respectively. One end member 20 is disposed on the battery cell 11 via the heat transfer plate 12, and the other end member 20 is disposed directly on the battery cell 11. The end member 20 includes a rectangular flat plate-shaped end plate (first member) 21 disposed on the battery unit 10 and a plate-shaped bracket (second member) disposed on the battery unit 10 and the end plate 21. 22.

  The end plate 21 extends over a wider range than the region where the battery cells 11 are arranged in the battery module 1 when viewed from the arrangement direction of the battery cells 11. Therefore, the end plate 21 extends to the outside of the outer edge of the battery cell 11 when viewed from the arrangement direction of the battery cells 11. The bracket 22 is housed in a narrower range than the region where the battery cells 11 are arranged in the battery module 1 when viewed from the arrangement direction of the battery cells 11. That is, when viewed from the arrangement direction of the battery cells 11, the outer edge of the bracket 22 is located inside the outer edge of the battery cell 11.

  The bracket 22 is fastened to the end plate 21 by a plurality of bolts 23. The bracket 22 is used when, for example, the battery module 1 is fixed to a housing (not shown) of a battery pack (not shown). For this reason, the bracket 22 is a portion that becomes a fastening portion to the housing of the battery pack and has a portion that extends in the arrangement direction of the battery cells 11, but the illustration thereof is omitted.

  The connection member 30 is arrange | positioned at each of the four corners of the end member 20 (end plate 21), for example. The connecting member 30 connects the end members 20 to each other so that the battery unit 10 is sandwiched between the pair of end members 20. Here, the connecting member 30 connects the end plates 21 to each other. More specifically, the connecting member 30 includes a long bar-shaped bolt 31 and nuts 32 that are screwed to both ends of the bolt 31.

  The bolts 31 are inserted through portions of the pair of end plates 21 that extend outward from the outer edges of the battery cells 11. The connecting member 30 fastens the end plates 21 together by screwing nuts 32 to both ends of the bolts 31 from the outside of the end plates 21 (opposite the battery unit 10). Thereby, the battery cell 11 and the heat transfer plate 12 are clamped by the end member 20 (end plate 21), and are unitized. Further, a restraining load is applied to the battery cell 11.

  Here, the end member 20 includes a plurality of regions arranged in a direction intersecting with the arrangement direction of the battery cells 11 (extending direction of the end plate 21). More specifically, the end member 20 includes a facing region 41 facing the battery cell 11, a connecting region 42 where the connecting member 30 is disposed, and an intermediate region 43 between the facing region 41 and the connecting region 42. Including. The facing region 41 is located substantially at the center of the end member 20 when viewed from the arrangement direction of the battery cells 11. The facing area 41 is an area facing the battery cell 11 in the end plate 21 and the bracket 22.

  The connection region 42 is located near the outer end of the end member 20 when viewed from the arrangement direction of the battery cells 11, and does not face the battery cell 11. The connection region 42 is a region where the connection member 30 in the end plate 21 is disposed (that is, a region through which the bolt 31 is inserted). The intermediate region 43 does not face the battery cell 11 when viewed from the arrangement direction of the battery cells 11. The intermediate region 43 is a region between the facing region 41 and the connection region 42 in the end plate 21. When viewed from the arrangement direction of the battery cells 11, the boundary between the intermediate region 43 and the facing region 41 coincides with the outer edge of the battery cell 11.

  The facing region 41 includes a portion consisting only of the end plate 21 and a portion consisting of the end plate 21 and the bracket 22. For this reason, the opposing region 41 includes a relatively thin portion and a relatively thick portion in the arrangement direction of the battery cells 11. On the other hand, the intermediate region 43 consists only of the end plate 21. Therefore, the thickness of the intermediate region 43 in the arrangement direction of the battery cells 11 is substantially the same as the thickness of the relatively thin portion of the facing region 41 and is substantially uniform in the extending direction of the end plate 21.

  Therefore, when comparing the entire opposing region 41 and the entire intermediate region 43, the average thickness of the intermediate region 43 in the arrangement direction of the battery cells 11 is larger than the average thickness of the opposing region 41 in the arrangement direction of the battery cells 11. thin. In other words, the intermediate region 43 includes the fragile portion 50 formed thinner than the average thickness of the facing region 41 in the arrangement direction of the battery cells 11. Here, the entire intermediate region 43 is the fragile portion 50 thinner than the average thickness of the facing region 41. The average thickness of the region is the average of the thickness of the region in the arrangement direction of the battery cells 11 in the extending direction of the end plate 21.

  If it is considered that the facing region 41 is a region including the bolt 23 that fastens the end plate 21 and the bracket 22 to each other in addition to the end plate 21 and the bracket 22, the thickness of the weakened portion 50 in the arrangement direction of the battery cells 11. This is equal to or less than the minimum thickness (the thickness of the end plate 21) of the facing region 41 in the arrangement direction of the battery cells 11.

  As described above, in the battery module 1 according to the present embodiment, the end members 20 are arranged at the end portions 10 a and 10 b of the battery unit 10 in the arrangement direction of the battery cells 11. And the end members 20 are mutually connected by the connection member 30 so that the battery unit 10 is clamped by the pair of end members 20. Moreover, the end member 20 has the opposing area | region 41 facing the battery cell 11 of the battery unit 10, the connection area | region 42 in which the connection member 30 is arrange | positioned, and the intermediate | middle area | region 43 between them.

  The intermediate region 43 includes a fragile portion 50 that is thinner than the average thickness of the facing region 41. Therefore, when the load applied to the connecting member 30 increases with the expansion of the battery cell 11, as shown in FIG. 3, the arrangement direction of the battery cells 11 starts from the weakened portion 50 (intermediate region 43). The end member 20 is deformed (for example, plastically deformed) in a direction in which the connection regions 42 facing each other approach each other. For this reason, even when the battery cell 11 expands, an increase in the load applied to the connecting member 30 is alleviated, and the breaking of the connecting member 30 can be suppressed.

  Further, even when the battery cell 11 expands due to such deformation of the end member 20, it is possible to suppress the binding load of the battery cell 11 from the end member 20 from becoming too large. For this reason, according to this battery module 1, it is possible to avoid the deterioration of the characteristics of the battery cell 11 and the shortening of the life of the battery cell 11 due to the restraining load of the battery cell 11 becoming larger than necessary. .

  In the battery module 1, the end member 20 has an end plate 21 disposed on the battery unit 10 and a bracket 22 disposed on the battery unit 10 and the end plate 21 and fastened to the end plate 21. . And the opposing area | region 41 is an area | region facing the battery cell 11 in the end plate 21 and the bracket 22, the connection area | region 42 is an area | region where the connection member 30 in the end plate 21 is arrange | positioned, and the intermediate | middle area | region 43 is This is a region between the facing region 41 and the connection region 42 in the end plate 21. For this reason, the opposed region 41 that is thicker on average than the thickness of the fragile portion 50 can be easily configured by the end plate 21 and the bracket 22. That is, formation of the weak part 50 is facilitated.

  Furthermore, in the battery module 1, assuming that the facing region 41 is a region including the bolt 23, the thickness of the fragile portion 50 in the arrangement direction of the battery cells 11 is the lowest of the facing region 41 in the arrangement direction of the battery cells 11. It is below the thickness (thickness of the end plate 21). For this reason, the deformation of the end member 20 accompanying the expansion of the battery cell 11 can be reliably started from the fragile portion 50. Thereby, when the battery cell 11 expand | swells, since the deformation | transformation of the opposing area | region 41 is avoided, the provision of the uniform restraint load to the battery cell 11 is maintained reliably.

  The above embodiment describes one embodiment of the battery module according to the present invention. Therefore, the battery module according to the present invention is not limited to the battery module described above. The battery module according to the present invention can be obtained by modifying the battery module 1 described above without departing from the scope of the claims.

  FIG. 4 is a partial cross-sectional view showing a modification of the battery module shown in FIG. As shown in FIG. 4A, in the battery module 1, the end member 20 may be only the end plate 21. In this case, since the end plate 21 is substantially flat, the thickness of the end plate 21 in the arrangement direction of the battery cells 11 is also substantially constant. However, in this case, a groove 43 s is provided in a part of the intermediate region 43 and is thinned. The groove 43s is provided in each of the intermediate regions 43 facing each other across the facing region 41, and extends substantially parallel to each other.

  Due to the formation of the groove 43 s, the weakened portion 50 thinner than the average thickness of the facing region 41 in the arrangement direction of the battery cells 11 is formed in the intermediate region 43. In this case, according to the expansion of the battery cell 11, the end member 20 is deformed starting from the fragile portion 50, so that an increase in load applied to the connecting member 30 is alleviated. Therefore, breakage of the connecting member 30, deterioration of the battery cell 11, and shortening of the life are suppressed.

  As shown in FIG. 4B, in the battery module 1, the end member 20 includes an end plate 21 made of a plurality of (here, two) portions having different thicknesses in the stacking direction of the battery cells 11. It can also be only. Here, the portion of the end plate 21 facing the battery cell 11 (opposing region 41) is relatively thick, and the other portions are relatively thin. With such a configuration, the weakened portion 50 thinner than the average thickness of the opposing region 41 in the arrangement direction of the battery cells 11 may be formed in the intermediate region 43 (the entire intermediate region 43 is the weakened portion 50).

  As described above, in the battery module 1, the average thickness of the facing region 41 with respect to the intermediate region 43 is determined in an arbitrary manner so that the end member 20 is deformed in the intermediate region 43 according to the expansion of the battery cell 11. A thinner fragile portion 50 can be provided.

  DESCRIPTION OF SYMBOLS 1 ... Battery module, 10a, 10b ... End part, 10 ... Battery unit, 11 ... Battery cell, 20 ... End member, 21 ... End plate (1st member), 22 ... Bracket (2nd member), 30 ... Connection member, 41... Opposing region, 42 .. connection region, 43 .. intermediate region, 50.

Claims (1)

A battery unit including a plurality of battery cells arranged along a predetermined direction;
A pair of end members respectively disposed at one end and the other end of the battery unit in the predetermined direction;
A connecting member that connects the end members to each other so that the battery unit is sandwiched by the pair of end members;
The end member has a flat plate shape, and has an opposing region facing the battery cell, a connecting region where the connecting member is disposed, and an intermediate region between the opposing region and the connecting region. ,
A groove is provided in a part of the intermediate region,
The intermediate region includes a fragile portion formed by the groove thinner than an average thickness of the facing region in the predetermined direction.
A battery module.

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