JP2018160335A - Battery module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a highly reliable battery module. SOLUTION: A battery module 1 includes an array 2 in which a plurality of battery cells 3 are arrayed, a pair of end plates 6 and 7 sandwiching the array 2 in an array direction D of the battery cells 3, and a pair of end plates. A restraint member 12 that has a restraint bolt 12 that connects 6 and 7 to each other and that applies a restraint load in the arrangement direction D to the array 2 is provided. The restraint member 8 includes an inner fastening portion 13 that fastens one end plate 6 from the inner side and an outer fastening portion 14 that fastens it from the outer side at the coupling position P of the restraint bolt 12. The strength of the outer fastening portion 14 with respect to the load in the arrangement direction D is higher than the strength of the inner fastening portion 13 with respect to the load in the arrangement direction D. [Selection diagram] Figure 1

Description

  The present invention relates to a battery module.

  As a conventional battery module, for example, there is one described in Patent Document 1. This conventional battery module includes an array formed by arranging a plurality of battery cells, a pair of end plates that sandwich the array in the array direction of the battery cells, and a restraint that applies a restraining load to the array in the array direction. And a member. The restraining member includes a restraining bolt inserted into an insertion hole provided in each end plate, and a pair of nuts screwed to the protruding portions of the restraining bolt protruding outward from each end plate. The restraint load is applied to the array by tightening the pair of end plates from the outside with these nuts.

JP 2001-236937 A

  In the battery module as described above, for example, when an impact load is applied due to vibration of a vehicle to be mounted, it is conceivable that the position of the restraint bolt in the insertion hole varies. When the position of the restraint bolt changes, the restraint bolt interferes with the end plate, and an excessive load may be applied to the restraint bolt at the interference position. In order to suppress the occurrence of such a situation, an inner fastening portion that tightens one end plate from the inside and an outer fastening portion that fastens from the outside are added at the binding position of the restraint bolt, and the restraint bolt and the end plate are firmly fixed. It is possible to do. However, when such a configuration is adopted, when the battery cell expands in the arrangement direction due to deterioration or overcharge, an excessive load is applied to the outer fastening portion via the end plate, and the contact surface with the end plate in the outer fastening portion There is a risk of problems such as sinking.

  The present invention has been made to solve the above-described problems, and an object thereof is to provide a highly reliable battery module.

  A battery module according to an aspect of the present invention includes an array formed by arranging a plurality of battery cells, a pair of end plates that sandwich the array in the array direction of the battery cells, and a constraint that connects the pair of end plates together. A restraint member having a bolt and applying a restraint load to the array body in the array direction, and the restraint member tightens one end plate from the inside at the coupling position of the restraint bolt and tightens from the outside. Including the outer fastening portion, the strength of the outer fastening portion with respect to the load in the arrangement direction is higher than the strength of the inner fastening portion with respect to the load in the arrangement direction.

  In this battery module, the end plate on one side is tightened from both sides by the inner fastening portion and the outer fastening portion at the binding position of the restraint bolt, and a large axial force (fastening force) is generated between the both fastening portions. It is possible to firmly fix the restraint bolt. For this reason, interference with a restraint volt | bolt and an end plate can be suppressed. Furthermore, in this battery module, the strength of the outer fastening portion with respect to the load in the arrangement direction is higher than the strength of the inner fastening portion with respect to the load in the arrangement direction. Thereby, the intensity | strength of an outer side fastening part can be ensured, and even when a battery cell expand | swells and a comparatively big load is applied to an outer side fastening part, it can suppress that a malfunction arises in an outer side fastening part. Therefore, according to this battery module, reliability can be improved.

  The area of the contact surface between the outer fastening portion and the one end plate may be larger than the area of the contact surface between the inner fastening portion and the one end plate. In this case, the strength of the outer fastening portion can be ensured by making the area of the contact surface between the outer fastening portion and the one end plate larger than the area of the contact surface between the inner fastening portion and the one end plate.

  In addition, the hardness of the outer fastening portion may be higher than the hardness of the inner fastening portion. In this case, the strength of the outer fastening portion can be ensured by making the hardness of the outer fastening portion higher than the hardness of the inner fastening portion.

  In addition, a fixing piece used for fixing to the outside is provided at each edge of the pair of end plates, and the restraining member includes a first restraining bolt that connects the pair of end plates at a position near the fixing piece. A second restraint bolt that connects the pair of end plates at a position away from the fixed piece, and the strength against the load in the arrangement direction of the outer fastening portion at the joining position of the second restraint bolt is It may be higher than the strength against the load in the arrangement direction of the outer fastening portion at the coupling position of the restraint bolt. When the end plate is fixed to the outside with a fixing piece provided at the edge, when the battery cell expands, the coupling position of the first restraining bolt that connects the pair of end plates at a position closer to the fixing piece There is a tendency that the load applied to the outer fastening portion at the coupling position of the second restraint bolt that connects the pair of end plates at a position distant from the fixed piece is larger than the load applied to the outer fastening portion in FIG. In this battery module, the strength against the load in the arrangement direction of the outer fastening portion at the coupling position of the second restraining bolt is higher than the strength against the load in the arrangement direction of the outer fastening portion at the coupling position of the first restraint bolt. Yes. Thereby, it can suppress suitably that a malfunction arises in the outer side fastening part in the joint position of the 2nd restraint bolt.

  According to the present invention, a highly reliable battery module can be provided.

It is a schematic sectional drawing which shows the battery module which concerns on embodiment. (A) is a schematic sectional drawing which shows a 1st modification, (b) is a schematic sectional drawing which shows a 2nd modification. It is a schematic sectional drawing which shows a 3rd modification.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. In the following description, the same reference numerals are used for the same or corresponding elements, and duplicate descriptions are omitted.

  FIG. 1 is a schematic cross-sectional view showing a battery module according to an embodiment. As shown in the figure, the battery module 1 according to the embodiment includes an array 2 in which a plurality of battery cells 3 are arrayed, a pair of end plates 6 and 7 sandwiching the array 2 in the array direction D, and an array And a restraining member 8 for applying a restraining load in the arrangement direction D to the body 2. The array body 2 further includes an elastic member 4 and a middle plate 5.

  The battery cell 3 constituting the array 2 is a nonaqueous electrolyte secondary battery such as a lithium ion secondary battery. In the present embodiment, the array body 2 includes eight battery cells 3. Adjacent battery cells 3 are bonded with, for example, a double-sided tape. Each battery cell 3 may be arranged in a state of being held by a resin cell holder. A heat transfer plate may be disposed between adjacent battery cells 3.

  Each battery cell 3 is formed by housing an electrode assembly and an electrolytic solution in a hollow case having a substantially rectangular parallelepiped shape, for example. A pair of electrode terminals (not shown) are provided apart from each other on the top surface of the case. One of the electrode terminals is a positive electrode terminal connected to the positive electrode of the electrode assembly, and the other of the electrode terminals is a negative electrode terminal connected to the negative electrode of the electrode assembly. Adjacent battery cells 3 and 3 are arranged so that the positive electrode terminal and the negative electrode terminal are adjacent to each other, and are connected in series by connecting the adjacent positive electrode terminal and the negative electrode terminal with a bus bar member. .

  The elastic member 4 is used for the purpose of preventing damage to the battery cell 3, the end plates 6, 7 and the restraining member 8 due to restraint load when the battery cell 3 is expanded. The elastic member 4 is formed in a rectangular plate shape by, for example, urethane rubber sponge. The elastic member 4 is disposed at one end of the array body 2 in the array direction D. Examples of other forming materials of the elastic member 4 include ethylene propylene diene rubber (EPDM), chloroprene rubber, and silicon rubber. The elastic member 4 is not limited to rubber but may be a spring material or the like.

  The middle plate 5 is, for example, a resin plate member. The middle plate 5 has a substantially rectangular plate shape corresponding to the shape of the battery cell 3 when viewed from the arrangement direction D, and the middle plate 5 is formed between the battery cell 3 and the elastic member 4 located on the most one side in the arrangement direction D. Arranged between. The middle plate 5 suppresses variation in load applied to each battery cell 3 from the elastic member 4. At the four corners of the middle plate 5, there are provided insertion holes 5a through which the restraint bolts 12 described later are inserted.

  The end plates 6 and 7 are, for example, metal plate members. As with the middle plate 5, the end plates 6 and 7 have a substantially rectangular plate shape corresponding to the shape of the battery cell 3 when viewed from the arrangement direction D. One end plate 6 is disposed so as to contact the elastic member 4. The other end plate 7 is disposed so as to contact the battery cell 3 located on the most other side in the arrangement direction D. At the four corners of the end plates 6 and 7, insertion holes 6a and 7a for inserting the restraining bolts 12 are provided, respectively.

  The edge 6b of the end plate 6 is provided with a fixing piece 9 used for fixing to the outside (here, the housing 10). The fixed piece 9 projects from the edge 6 b of the end plate 6 at a substantially right angle to the end plate 6. The fixing piece 9 is provided with a plurality of insertion holes 9 a through which the fixing bolts 11 are inserted along the edge 6 b of the end plate 6. A similar fixing piece 9 is also provided on the edge 7 b of the end plate 7. The battery module 1 is fixed to the casing 10 by screwing the fixing bolts 11 passed through the insertion holes 9 a into the bolt holes 10 a provided in the casing 10.

  The restraining member 8 includes a restraining bolt 12, an inner fastening portion 13, and an outer fastening portion 14. The restraint bolt 12 is a long bolt having a head portion 12a, and a screw portion 12b is formed at the tip. The restraint bolt 12 is stretched between the pair of end plates 6 and 7, and connects the end plates 6 and 7 to each other. The restraining member 8 includes, as restraining bolts 12, a first restraining bolt 12 </ b> A that connects the pair of end plates 6, 7 at a position near the fixing piece 9, and a pair of end plates 6 at a position away from the fixing piece 9. There are two second restraint bolts 12B that connect the seven members together.

  The restraint bolt 12 is passed through the insertion holes 5a, 6a, and 7a so that the middle plate 5 and the end plates 6 and 7 are inserted from the end plate 7 side. An outer fastening portion 14 made of a nut is screwed into the threaded portion 12 b of the restraining bolt 12 protruding from the end plate 6. The outer fastening portion 14 fastens the end plate 6 from the outside in the arrangement direction D, and sandwiches the pair of end plates 6 and 7 between the head 12 a of the restraining bolt 12. As a result, the battery cell 3, the elastic member 4 and the middle plate 5 are sandwiched and unitized, and a predetermined restraining load is applied to the battery cell 3, the elastic member 4 and the middle plate 5 via the end plates 6 and 7. Has been. This restraining load is balanced with the elastic repulsion force of the elastic member 4 and is, for example, about several hundred N.

  Further, an inner fastening portion 13 made of a nut is screwed to the threaded portion 12 b of the restraining bolt 12. The inner fastening portion 13 fastens the end plate 6 from the inner side in the arrangement direction D, and sandwiches the end plate 6 with the outer fastening portion 14 at the coupling position P of the restraint bolt 12. The coupling position P of the restraint bolt 12 is a position corresponding to the restraint bolt 12 in the end plate 6, and more specifically, is a peripheral portion of the insertion hole 6a. A large axial force acts on the end plate 6 by being tightened from both sides by the fastening force of the inner fastening portion 13 and the outer fastening portion 14. This axial force is larger than the restraining load, for example, about several thousand N.

  The inner fastening portion 13 includes an inner fastening portion 13A at the coupling position P of the first restraining bolt 12A and an inner fastening portion 13B at the coupling position P of the second restraining bolt 12B. The outer fastening portion 14 includes an outer fastening portion 14A at the coupling position P of the first restraining bolt 12A and an outer fastening portion 14B at the coupling position P of the second restraining bolt 12B. The inner fastening portion 13 and the outer fastening portion 14 have similar outer shapes when viewed from the arrangement direction D. In this example, the outer shape of the inner fastening portion 13 and the outer fastening portion 14 when viewed from the arrangement direction D is a hexagonal shape. In this embodiment, the inner side fastening part 13 and the outer side fastening part 14 are comprised with the mutually same material. The thicknesses of the inner fastening portion 13 and the outer fastening portion 14 are equal to each other.

  In the battery module 1, with respect to the inner fastening portion 13A and the outer fastening portion 14A at the coupling position P of the first restraining bolt 12A, the two-side width (distance between two opposing side surfaces) D1 of the outer fastening portion 14A is the inner fastening. By being wider than the two-surface width D2 of the portion 13A, the area of the seating surface (contact surface with the end plate 6) of the outer fastening portion 14A is larger than the area of the seating surface of the inner fastening portion 13A. . Thereby, the strength with respect to the load in the arrangement direction D of the outer fastening portion 14A is higher than the strength with respect to the load in the arrangement direction D of the inner fastening portion 13A.

  Similarly, for the inner fastening portion 13B and the outer fastening portion 14B at the coupling position P of the second restraining bolt 12B, the two-sided width (distance between two opposing side surfaces) D3 of the outer fastening portion 14B is the inner fastening portion 13B. By being wider than the two-surface width D2, the area of the seating surface of the outer fastening portion 14B is larger than the area of the seating surface of the inner fastening portion 13B. Thereby, the intensity | strength with respect to the load of the arrangement direction D of the outer side fastening part 14B is higher than the intensity | strength with respect to the load of the arrangement direction D of the inner side fastening part 13B. The two-surface width of the inner fastening portion 13B is equal to the two-surface width D2 of the inner fastening portion 13A.

  Further, since the two-surface width D3 of the outer fastening portion 14B is wider than the two-surface width D1 of the outer fastening portion 14A, the area of the seating surface of the outer fastening portion 14B is larger than the area of the seating surface of the outer fastening portion 14A. Is also getting wider. Thereby, the strength with respect to the load in the arrangement direction D of the outer fastening portion 14B is higher than the strength with respect to the load in the arrangement direction D of the outer fastening portion 14A. In addition, not only the width across flats, but the strength relationship as described above may be realized by changing the diagonal distance, for example. For example, when the outer shape of the inner fastening portion 13 and the outer fastening portion 14 as viewed from the arrangement direction D is circular, the above-described strength relationship may be realized by changing the diameter. Thus, the external shape of the inner side fastening part 13 and the outer side fastening part 14 when viewed from the arrangement direction D is not limited, and may be any shape.

The area of the seating surface of the inner fastening portion 13 is set so that the seating surface does not sink due to the initial fastening force (axial force of the restraining bolt 12) applied when the battery module 1 is assembled. More specifically, for example, the following equation is set.
Bearing surface depression stress [Pa] of the inner fastening portion 13> initial fastening force [N] / seat surface area [m ² ] of the inner fastening portion 13.
Here, the seating surface depression stress is a value determined by the material constituting the inner fastening portion 13. The initial fastening force is larger than the sliding direction load applied to the seating surface of the inner fastening portion 13 by vibration or impact. That is, the initial fastening force satisfies the following formula.
Initial fastening force [N] x bearing friction coefficient> sliding direction load [N]

  With respect to the outer fastening portion 14, when the battery cell 3 expands in the arrangement direction D due to deterioration or overcharge, a load is applied to the end plate 6 from the elastic member 4 that is compressed and deformed, and the outer fastening portion 14 is interposed via the end plate 6. A large load is applied. Therefore, the area of the seating surface of the outer fastening portion 14 is set wider than the area of the seating surface of the inner fastening portion 13 so that the seating surface does not sink even when the load is applied in addition to the initial fastening force. .

  In particular, when the end plates 6 and 7 are fixed to the housing 10 at the fixing pieces 9 provided on the edges 6b and 7b as in the present embodiment, the position close to the fixing pieces 9 when the battery cell 3 expands. The pair of end plates 6 and 7 are moved away from the fixed piece 9 rather than the load applied to the outer fastening portion 14A at the coupling position P of the first restraining bolt 12A for connecting the pair of end plates 6 and 7 to each other. There is a tendency that the load applied to the outer fastening portion 14B at the coupling position P of the second restraining bolt 12B to be coupled becomes large. This is because the end plates 6, 7 are fixed to the housing 10 on the fixed piece 9 side, and the end plates 6, 7 have higher rigidity at the portion near the fixed piece 9, so the end plates 6, 7 This is because the end of the side farther from the fixed piece 9 tends to be deformed so that the second constraining bolt 12B extends. Therefore, in the battery module 1, the area of the seating surface of the outer fastening portion 14B is set wider than the area of the seating surface of the outer fastening portion 14A.

  Next, an example of the assembly process of the battery module 1 will be described. First, the plurality of battery cells 3, the elastic member 4, the middle plate 5, and the end plate 7 are arranged along the arrangement direction D, and the restraint bolts 12 are inserted into the middle plate 5 and the end plate 7 from the end plate 7 side. Subsequently, the inner fastening portion 13 is screwed into the screw portion 12 b of the restraining bolt 12. At this time, the inner fastening portion 13 is positioned at a position inside the assembly position of the end plate 6 and outside the assembly position of the middle plate 5 so as not to hinder the work in a subsequent process.

  Subsequently, the end plate 6 is disposed so as to be adjacent to the elastic member 4, and the restraint bolt 12 is inserted into the end plate 6. Subsequently, the outer fastening portion 14 is screwed into the screw portion 12 b of the restraint bolt 12, and a predetermined restraint load is applied to the battery cell 3, the elastic member 4, and the middle plate 5. Subsequently, by rotating the inner fastening portion 13 and moving it toward the outside in the arrangement direction D, the end plate 6 is fastened from both sides by the inner fastening portion 13 and the outer fastening portion 14, and a predetermined axial force is applied to the end plate 6. Act. Thus, the battery module 1 is manufactured. In order to improve the assemblability, the clearance between the insertion holes 6a and 7a of the end plates 6 and 7 and the shaft portion of the restraining bolt 12 is the same as that between the insertion hole 5a of the middle plate 5 and the shaft portion of the restraining bolt 12. The clearance between is larger.

  As described above, in the battery module 1 of the present embodiment, the end plate 6 is fastened from both sides by the inner fastening portion 13 and the outer fastening portion 14 at the coupling position P of the restraint bolt 12, and the inner fastening portion 13 and the outer fastening portion 14. By generating a large axial force (fastening force) between them, the restraint bolt can be firmly fixed to the end plate 6. For this reason, interference with the restraint bolt 12 and the end plate 6 can be suppressed. Further, in the battery module 1, the strength of the outer fastening portion 14 against the load in the arrangement direction D is higher than the strength of the inner fastening portion 13 against the load in the arrangement direction D. Thereby, the intensity | strength of the outer side fastening part 14 can be ensured, and even when the battery cell 3 expand | swells and a comparatively big load is applied to the outer side fastening part 14, it can suppress that a malfunction arises in the outer side fastening part 14. FIG. Therefore, according to the battery module 1, reliability can be improved.

  In the battery module 1, the area of the contact surface between the outer fastening portion 14 and the end plate 6 is wider than the area of the contact surface between the inner fastening portion 13 and the end plate 6. Thereby, the intensity | strength of the outer side fastening part 14 is securable by making the area of the contact surface of the outer side fastening part 14 and the end plate 6 larger than the area of the contact surface of the inner side fastening part 13 and the end plate 6.

  In the battery module 1, the strength against the load in the arrangement direction D of the outer fastening portion 14B at the joining position P of the second restraining bolt 12B is such that the strength of the outer fastening portion 14A in the joining position P of the first restraining bolt 12A is It is higher than the strength against the load of D. Thereby, it can suppress suitably that a malfunction arises in the outer side fastening part 14B in the joint position P of the 2nd restraint bolt 12B.

  Although one embodiment of the present invention has been described above, the present invention is not limited to the above embodiment. For example, you may be comprised like the 1st modification shown by Fig.2 (a), for example. In the first modification, the constraining bolt 12 is a stepped bolt in which a screw portion 12d having a smaller diameter than the cylindrical portion 12c is provided on the tip side of the cylindrical portion 12c, and the inner fastening portion 13 is connected to the cylindrical portion 12c and the screw. It is comprised by the level | step-difference part 12e between the parts 12d. The step portion 12e has, for example, a step surface perpendicular to the arrangement direction D. Such a constraining bolt 12 is formed, for example, by scraping the tip portion of a cylindrical base material and providing a screw portion 12d at the tip portion. A screw portion is provided on the proximal end side of the cylindrical portion 12c, and, for example, a double nut is screwed to the screw portion. In this example, a pair of end plates 6 and 7 are sandwiched between the outer fastening portion 14 and the double nut. Further, the end plate 6 is sandwiched between the stepped portion 12e (inner fastening portion 13) and the outer fastening portion 14. The relationship of the strength with respect to the load in the arrangement direction D of the inner fastening portions 13A, 13B and the outer fastening portions 14A, 14B is the same as that in the above embodiment.

  In the assembly process of the first modified example, first, after the restraint bolt 12 is inserted through the end plate 6, the outer fastening portion 14 is screwed into the screw portion 12 b of the restraint bolt 12, and the end plate 6 is joined to the inner fastening portion 13. Tighten from both sides by the (step 12e) and the outer fastening part 14. Subsequently, the plurality of battery cells 3, the elastic member 4, the middle plate 5, and the end plate 6 are arranged along the arrangement direction D, and the restraint bolts 12 are inserted into the middle plate 5 and the end plate 7 from the end plate 6 side. . Subsequently, a double nut is screwed into the screw portion on the proximal end side of the restraint bolt 12, and a predetermined restraint load is applied to the battery cell 3, the elastic member 4, and the middle plate 5. Thus, the battery module 1 of the first modification is manufactured. Also by such a 1st modification, while being able to suppress interference with the restraint bolt 12 and the end plate 6 similarly to the said embodiment, it can suppress that a malfunction arises in the outer side fastening part 14. FIG.

  Moreover, you may be comprised like the 2nd modification shown by FIG.2 (b). In the second modification, the inner fastening portion 13 is configured by a flange portion 12f provided on the restraining bolt 12. The flange portion 12f has an annular shape, for example, and is coupled to one end portion side of the restraint bolt 12 by welding or the like. Similar to the first modified example, a double nut is screwed to a screw portion provided on the other end portion side of the restraining bolt 12, and a pair of end plates 6, between the outer fastening portion 14 and the double nut. 7 is sandwiched. Further, the end plate 6 is sandwiched between the flange portion 12 f (inner fastening portion 13) and the outer fastening portion 14. The relationship of the strength with respect to the load in the arrangement direction D of the inner fastening portions 13A, 13B and the outer fastening portions 14A, 14B is the same as that in the above embodiment. The battery module 1 of the second modification is manufactured by the same assembly process as that of the first modification. According to such a second modified example as well, the interference between the restraining bolt 12 and the end plate 6 can be suppressed, and the occurrence of defects in the outer fastening portion 14 can be suppressed as in the above embodiment.

  Moreover, you may comprise like the 3rd modification shown by FIG. In the third modification, the outer fastening portion 14 is configured by the head portion 12 g of the restraint bolt 12. A screw portion 12h into which the inner fastening portion 13 is screwed is provided at a portion adjacent to the head portion 12g in the restraint bolt 12. Similar to the first and second modified examples, a double nut is screwed to a screw portion provided on the proximal end side (the side opposite to the head portion 12g) of the restraining bolt 12, and the outer fastening portion 14 and the double fastening portion are connected. A pair of end plates 6 and 7 are sandwiched between the nuts. Further, the end plate 6 is sandwiched between the inner fastening portion 13 and the head portion 12g (outer fastening portion 14). The relationship of the strength with respect to the load in the arrangement direction D of the inner fastening portions 13A, 13B and the outer fastening portions 14A, 14B is the same as that in the above embodiment. In the third modification, the restraining bolt 12 is inserted through the middle plate 5 and the end plate 7 from the end plate 6 side. In the assembly process of the third modified example, first, after the constraining bolt 12 is inserted into the end plate 6, the inner fastening part 13 is screwed into the screw part 12 h of the restraining bolt 12, and the end plate 6 is joined to the inner fastening part 13. And it tightens from both sides by the outer side fastening part 14 (head 12g). Other points are the same as in the case of the first modification. According to the third modified example as well, the interference between the restraining bolt 12 and the end plate 6 can be suppressed, and the occurrence of a problem in the outer fastening portion 14 can be suppressed as in the above embodiment.

  Moreover, in the said embodiment, since the area of the seating surface of the outer side fastening part 14 is larger than the area of the seating surface of the inner side fastening part 13, the intensity | strength with respect to the load of the arrangement direction D of the outer side fastening part 14 is inner side fastening. Although it was higher than the intensity | strength with respect to the load of the arrangement | sequence direction D of the part 13, it replaces with or in addition to this, and the hardness relationship of the outer fastening part 14 is higher than the hardness of the inner fastening part 13 concerned. May be realized. For example, the hardness of the outer fastening portion 14 may be made higher than the hardness of the inner fastening portion 13 by using a material having higher rigidity than the material constituting the inner fastening portion 13 as the material constituting the outer fastening portion 14. . As a combination of such materials, a combination of non-quenched steel (inner fastening portion 13) and hardened steel (outer fastening portion 14), aluminum (inner fastening portion 13) and steel (outer fastening portion 14). ) And the like. Moreover, in the said embodiment, the arrangement | positioning number and arrangement | positioning aspect of the elastic member 4 are not limited, For example, the some elastic member 4 may be arrange | positioned between the arrangement | sequence end of the array body 2, and / or each battery cell 3. FIG.

DESCRIPTION OF SYMBOLS 1 ... Battery module, 2 ... Array, 3 ... Battery cell, 4 ... Elastic member, 6, 7 ... End plate, 8 ... Restraint member, 12 ... Restraint bolt, 12A ... 1st restraint bolt, 12B ... 2nd Restraint bolt, 13 ... inner fastening portion, 14 ... outer fastening portion, 13A ... inner fastening portion at the coupling position of the first restraining bolt, 13B ... inner fastening portion at the coupling position of the second restraining bolt, 14A ... first Outer fastening portion at the binding position of the restraint bolt, 14B... Outer fastening portion at the joint position of the second restraint bolt, D.

Claims (4)

An array formed by arranging a plurality of battery cells;
A pair of end plates that sandwich the array in the array direction of the battery cells;
A restraint bolt that connects the pair of end plates to each other, and a restraint member that applies a restraint load in the array direction to the array,
The restraining member includes an inner fastening portion that fastens one of the end plates from the inside and an outer fastening portion that fastens from the outside at the binding position of the restraining bolt,
The battery module in which the strength of the outer fastening portion with respect to the load in the arrangement direction is higher than the strength of the inner fastening portion with respect to the load in the arrangement direction.   The battery module according to claim 1, wherein an area of a contact surface between the outer fastening portion and the one end plate is larger than an area of a contact surface between the inner fastening portion and the one end plate.   The battery module according to claim 1, wherein a hardness of the outer fastening portion is higher than a hardness of the inner fastening portion. Fixing pieces used for fixing to the outside are provided at the edges of the pair of end plates,
The restraining member includes a first restraining bolt that couples the pair of end plates at a position closer to the fixing piece, and a second restraining bolt that couples the pair of end plates at a position away from the fixing piece. And having
The strength with respect to the load in the arrangement direction of the outer fastening portion at the coupling position of the second restraint bolt is higher than the strength with respect to the load in the arrangement direction of the outer fastening portion at the coupling position of the first restraint bolt. The battery module according to any one of claims 1 to 3.

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