JP2019149342A - Battery pack - Google Patents

Abstract

To provide a battery pack capable of suppressing that excessive stress loads on an electric connection portion between battery stacks when a vibration or a shock is inputted from the outside.SOLUTION: A battery pack includes a first battery stack 12A, a second battery stack 12B and a case body 31. Each of the first battery stack 12A and the second battery stack 12B comprises: a plurality of single cells laminated in one direction and electrically connected to each other; a pair of end plates 22 clamping the plurality of single cells in the lamination direction; a first bath bar 61 electrically connected with the single cells 21; and a second bath bar 41 provided in the bottom wall 32 of the case body 31 and electrically connecting the first bath bars 61 between the first battery stack 12A and the second battery stack 12B. At least a part of the first bath bar 61 is incorporated in the end plate 22.SELECTED DRAWING: Figure 4

Description

  The present disclosure relates to a battery pack.

  Regarding a conventional battery pack, for example, Japanese Unexamined Patent Application Publication No. 2014-1117068 (Patent Document 1) discloses an assembled battery including a first battery module and a second battery module.

  Each battery module has a plurality of battery cells arranged such that the positive electrode and the negative electrode are staggered. A bus bar is provided so as to span between the positive electrode of one of the battery cells adjacent to each other and the negative electrode of the other battery cell. The bus bar connected to the negative electrode of the battery cell in the first battery module and the bus bar connected to the positive electrode of the battery cell in the second battery module are connected via electrical wiring.

JP 2014-1117068 A

  As disclosed in Patent Document 1 described above, an assembled battery (battery pack) in which two battery modules (battery stacks) are connected via electric wiring is known. In such a battery pack, when vibration or impact is input to the battery pack from the outside, excessive stress may be applied to the terminals of the battery cell (unit cell) via the electrical wiring.

  Accordingly, an object of the present disclosure is to solve the above-described problem, and a battery that suppresses excessive stress from being applied to an electrical connection portion between battery stacks when vibration or impact is input from the outside. Is to provide a pack.

  A battery pack according to the present disclosure includes a first battery stack and a second battery stack, and a case body that houses the first battery stack and the second battery stack. Each of the first battery stack and the second battery stack is stacked in one direction and is electrically connected to each other, arranged on both sides of the plurality of single cells, and the plurality of single cells are stacked in the stacking direction. And a first bus bar electrically connected to the single cell. At least a part of the first bus bar is built in the end plate. The case body has an inner wall that defines an internal space for accommodating the first battery stack and the second battery stack. The battery pack further includes a second bus bar provided on the inner wall and electrically connecting the first bus bars to each other between the first battery stack and the second battery stack.

  According to the battery pack configured as described above, the first bus bar and the second bus bar that electrically connect the first battery stack and the second battery stack are provided integrally with the end plate and the case body. For this reason, even when vibration or impact is input to the battery pack from the outside, it is difficult for vibration or impact to be applied only to the first bus bar and the second bus bar. Thereby, it can suppress that an excessive stress is loaded to the electrical connection part between battery stacks.

  As described above, according to the present disclosure, there is provided a battery pack that suppresses excessive stress from being applied to an electrical connection portion between battery stacks when vibration or impact is input from the outside. be able to.

3 is a perspective view showing a battery pack according to Embodiment 1. FIG. It is a top view which shows the battery pack in FIG. FIG. 2 is an exploded view showing the battery pack in FIG. 1. It is sectional drawing which shows the battery pack seen from the arrow direction on the IV-IV line in FIG. 6 is a perspective view showing a battery pack according to Embodiment 2. FIG. It is a top view which shows the battery pack in FIG. FIG. 6 is an exploded view showing the battery pack in FIG. 5. It is sectional drawing which shows the battery pack seen from the arrow direction on the VIII-VIII line in FIG. It is sectional drawing which shows the battery pack seen from the arrow direction on the IX-IX line in FIG.

  Embodiments of the present disclosure will be described with reference to the drawings. In the drawings referred to below, the same or corresponding members are denoted by the same reference numerals.

(Embodiment 1)
1 is a perspective view showing a battery pack according to Embodiment 1. FIG. FIG. 2 is a top view showing the battery pack in FIG.

  Referring to FIGS. 1 and 2, battery pack 10 is for driving a vehicle. For example, an internal combustion engine such as a gasoline engine or a diesel engine and a motor powered by a chargeable / dischargeable battery are used as a power source. Installed in a hybrid vehicle, a plug-in hybrid vehicle capable of external charging, or an electric vehicle.

  First, the overall structure of the battery pack 10 will be described. The battery pack 10 includes a first battery stack 12 </ b> A and a second battery stack 12 </ b> B, a case body 31, and a fixing bracket 51.

  Each of the first battery stack 12 </ b> A and the second battery stack 12 </ b> B includes a plurality of single cells 21, a pair of end plates 22, a restraining band 28, and a plurality of inter-cell bus bars 25.

  The unit cell 21 is a lithium ion battery. The plurality of unit cells 21 are stacked in one direction (the direction indicated by the arrow 101 in the drawing, hereinafter also referred to as “the stacking direction of the unit cells 21”). The unit cell 21 has a rectangular parallelepiped thin plate shape. The plurality of unit cells 21 are stacked such that the side surfaces having the largest area among the plurality of side surfaces forming the appearance of the unit cell 21 face each other. The plurality of unit cells 21 are stacked such that the stacking direction is parallel to the thickness direction of each unit cell 21.

  The unit cell 21 has a positive electrode terminal 24p and a negative electrode terminal 24n. The positive electrode terminal 24p and the negative electrode terminal 24n protrude to the upper surface side of the unit cell 21. The plurality of unit cells 21 are stacked such that the positive electrode terminal 24p and the negative electrode terminal 24n are arranged between the unit cells 21 adjacent in the stacking direction. The inter-cell bus bar 25 is provided so as to connect the positive electrode terminal 24p and the negative electrode terminal 24n between the single cells 21 adjacent in the stacking direction. The plurality of single cells 21 are electrically connected to each other in series.

  The pair of end plates 22 are disposed on both sides of the plurality of unit cells 21. The plurality of unit cells 21 are sandwiched between a pair of end plates 22 in the stacking direction. The end plate 22 is composed of a flat plate whose unit cell 21 is stacked in the thickness direction. The end plate 22 has a rectangular shape when viewed from the stacking direction of the unit cells 21. The end plate 22 is made of resin.

  The first battery stack 12 </ b> A has a pair of end plates 22 </ b> A as the pair of end plates 22. The second battery stack 12B includes a pair of end plates 22B as the pair of end plates 22.

  The restraining band 28 connects the pair of end plates 22. The restraint band 28 extends linearly along the stacking direction of the unit cells 21 and is connected to the pair of end plates 22 at both ends thereof.

  The first battery stack 12A as a whole has a rectangular parallelepiped shape. The first battery stack 12 </ b> A has a rectangular shape in which the stacking direction of the unit cells 21 is the longitudinal direction and the direction orthogonal to the stacking direction of the unit cells 21 (the direction indicated by the arrow 102) is the short direction. . The second battery stack 12B has a rectangular parallelepiped shape similar to that of the first battery stack 12A.

  The case body 31 is composed of a housing (in FIG. 1, only the bottom of the case body 31 is shown for convenience of illustration). The first battery stack 12 </ b> A and the second battery stack 12 </ b> B are accommodated in the case body 31.

  The case body 31 has a bottom wall 32. The bottom wall 32 defines an internal space that houses the first battery stack 12A and the second battery stack 12B. The first battery stack 12 </ b> A and the second battery stack 12 </ b> B are placed on the bottom wall 32.

  The first battery stack 12 </ b> A and the second battery stack 12 </ b> B are arranged adjacent to each other on the bottom wall 32. The first battery stack 12A and the second battery stack 12B are arranged in the horizontal direction. The first battery stack 12A and the second battery stack 12B are arranged so that the stacking direction of the single cells 21 in the first battery stack 12A and the stacking direction of the single cells 21 in the second battery stack 12B are parallel to each other. ing. At both ends in the stacking direction of the unit cells 21, the end plate 22A in the first battery stack 12A and the end plate 22B in the second battery stack 12B are arranged at intervals.

  The fixing bracket 51 fixes the first battery stack 12 </ b> A and the second battery stack 12 </ b> B to the case body 31.

  The fixing bracket 51 is made of an L-shaped plate material. The fixed bracket 51 is addressed to the corners of the end plate 22 and the bottom wall 32 at both ends in the stacking direction of the unit cells 21. The fixing bracket 51 is fastened to the bottom wall 32 of the case body 31 by fastening members such as bolts.

  The first battery stack 12A and the second battery stack 12B are electrically connected to each other. Next, an electrical connection structure between the first battery stack 12A and the second battery stack 12B will be described.

  3 is an exploded view showing the battery pack in FIG. 4 is a cross-sectional view showing the battery pack as seen from the direction of the arrow on the line IV-IV in FIG.

  Referring to FIGS. 1 to 4, each of first battery stack 12 </ b> A and second battery stack 12 </ b> B further includes a first bus bar 61.

  At least a part of the first bus bar 61 is built in the end plate 22. At least a part of the first bus bar 61 is embedded in the end plate 22. The first bus bar 61 is insert-molded in the end plate 22. The first bus bar 61 is provided integrally with the end plate 22.

  The end plate 22 has an upper surface 22r and a lower surface 22s. The lower surface 22s faces the bottom wall 32 in the vertical direction. The upper surface 22r is disposed on the back side of the lower surface 22s.

  The first bus bar 61 has a first connection part 62 and a second connection part 63 as its constituent parts. The first bus bar 61 extends in a plate shape between the first connection portion 62 and the second connection portion 63. The first connection part 62 is exposed to the outside of the end plate 22. The first connection part 62 is disposed on the upper surface 22 r of the end plate 22. The first bus bar 61 extends from the first connection portion 62 to the second connection portion 63 through the inside of the end plate 22. The second connection part 63 is built in the end plate 22. The second connection portion 63 is disposed immediately above the lower surface 22 s of the end plate 22.

  A bus bar insertion portion 27 is provided on the end plate 22. The bus bar insertion portion 27 includes an opening that opens on the lower surface 22 s of the end plate 22. The second connection part 63 of the first bus bar 61 is arranged in the bus bar insertion part 27.

  The first bus bar 61 is electrically connected to the unit cell 21 of each battery stack of the first battery stack 12A and the second battery stack 12B.

  The first battery stack 12 </ b> A includes a first bus bar 61 </ b> A as the first bus bar 61. The first bus bar 61A (more specifically, the first connection portion 62 of the first bus bar 61A) is connected to the positive terminal 24p of the unit cell 21 in the first battery stack 12A via the inter-cell bus bar 25. . The second battery stack 12 </ b> B includes a first bus bar 61 </ b> B as the first bus bar 61. The first bus bar 61B (more specifically, the first connection portion 62 of the first bus bar 61B) is connected to the negative electrode terminal 24n of the unit cell 21 in the second battery stack 12B via the inter-cell bus bar 25. .

  The battery pack 10 further includes a second bus bar 41. The second bus bar 41 is provided on the bottom wall 32. The second bus bar 41 is fixed to the bottom wall 32. The second bus bar 41 is provided integrally with the bottom wall 32.

  The second bus bar 41 electrically connects the first bus bars 61 to each other between the first battery stack 12A and the second battery stack 12B. The second bus bar 41 electrically connects the first bus bar 61A of the first battery stack 12A and the first bus bar 61B of the second battery stack 12B.

  The second bus bar 41 includes a base portion 42, a first connection portion 43, and a second connection portion 44 as constituent parts thereof. The base 42 extends linearly along the bottom wall 32. The base 42 extends in the direction in which the first battery stack 12A and the second battery stack 12B are arranged. The first connection part 43 and the second connection part 44 are provided so as to rise from both ends of the base part 42.

  The first connection portion 43 extends from the bottom wall 32 toward the end plate 22A of the first battery stack 12A, and is inserted into the bus bar insertion portion 27 at the tip thereof. The first connection portion 43 is connected to the second connection portion 63 of the first bus bar 61 </ b> A inside the bus bar insertion portion 27. The second connection portion 44 extends from the bottom wall 32 toward the end plate 22B of the second battery stack 12B, and is inserted into the bus bar insertion portion 27 at the tip thereof. The second connection portion 44 is connected to the second connection portion 63 of the first bus bar 61B inside the bus bar insertion portion 27.

  The first battery stack 12A and the second battery stack 12B are electrically connected to each other in series by the first bus bar 61 and the second bus bar 41.

  According to such a configuration, when vibration or impact is input to the battery pack 10 from the outside, it is possible to prevent the first bus bar 61 and the second bus bar 41 from vibrating alone. Thereby, it is possible to suppress an excessive stress from being applied to the positive electrode terminal 24p and the negative electrode terminal 24n of the unit cell 21 serving as an electrical connection portion between the first cell stack 12A and the second cell stack 12B. The terminal structure can be simplified.

  Further, as shown in FIG. 3, the second bus bar 41 is assembled in advance to the case body 31 during the assembly process of the battery pack 10. Next, while the first battery stack 12A and the second battery stack 12B are placed on the bottom wall 32 of the case body 31, the first connection portion 43 and the second connection portion 44 of the second bus bar 41 are connected to the end plate 22A. And it inserts in the bus-bar insertion part 27 of the end plate 22B.

  According to such a process, since the connection of the first bus bar 61 and the second bus bar 41 is completed together with the assembly of the first battery stack 12A and the second battery stack 12B to the case body 31, the assembly process of the battery pack 10 is performed. It can be simplified.

  The structure of the battery pack 10 according to the first embodiment described above will be described together. The battery pack 10 according to the present embodiment includes the first battery stack 12A, the second battery stack 12B, the first battery stack 12A, and And a case body 31 that houses the second battery stack 12B. Each of the first battery stack 12A and the second battery stack 12B is stacked in one direction and is electrically connected to each other, and is disposed on both sides of the plurality of unit cells 21. And a first bus bar 61 electrically connected to the unit cell 21. At least a part of the first bus bar 61 is built in the end plate 22. The case body 31 has a bottom wall 32 as an inner wall that defines an internal space that accommodates the first battery stack 12A and the second battery stack 12B. The battery pack 10 further includes a second bus bar 41 that is provided on the bottom wall 32 and electrically connects the first bus bars 61 to each other between the first battery stack 12A and the second battery stack 12B.

  According to the battery pack 10 of Embodiment 1 configured as described above, when vibration or impact is input from the outside, the electrical connection portion between the first battery stack 12A and the second battery stack 12B is provided. It is possible to suppress the application of excessive stress.

(Embodiment 2)
FIG. 5 is a perspective view showing the battery pack according to the second embodiment. FIG. 6 is a top view showing the battery pack in FIG. FIG. 7 is an exploded view showing the battery pack in FIG. FIG. 8 is a cross-sectional view showing the battery pack as seen from the direction of the arrow on the line VIII-VIII in FIG. 9 is a cross-sectional view showing the battery pack as seen from the direction of the arrow on the line IX-IX in FIG.

  The battery pack in the present embodiment has basically the same structure as that of battery pack 10 in the first embodiment. Hereinafter, the description of the overlapping structure will not be repeated.

  With reference to FIGS. 5 to 9, battery pack 110 in the present embodiment includes first battery stack 112 </ b> A and second battery stack 112 </ b> B, case body 131, and fixing bracket 151.

  First battery stack 112A and second battery stack 112B correspond to first battery stack 12A and second battery stack 12B in the first embodiment, respectively. Each of the first battery stack 112 </ b> A and the second battery stack 112 </ b> B includes a plurality of single cells 21, a pair of end plates 122, a restraining band 28, and a plurality of inter-cell bus bars 25.

  The pair of end plates 122 corresponds to the pair of end plates 22 in the first embodiment. The first battery stack 112 </ b> A includes a pair of end plates 122 </ b> A as the pair of end plates 122. The second battery stack 112B includes a pair of end plates 122B as the pair of end plates 122.

  The fixing bracket 151 corresponds to the fixing bracket 51 in the first embodiment. The first battery stack 112 </ b> A has a fixed bracket 151 </ b> A as the fixed bracket 151. The second battery stack 112B includes a fixed bracket 151B as the fixed bracket 151.

  Each of first battery stack 112 </ b> A and second battery stack 112 </ b> B further includes a first bus bar 161. First bus bar 161 is provided corresponding to first bus bar 61 in the first embodiment.

  End plate 122 has upper surface 122r and lower surface 122s corresponding to upper surface 22r and lower surface 22s in the first embodiment, respectively.

  The first bus bar 161 has a first connection part 162 and a second connection part 163 as its constituent parts. The first bus bar 161 extends in a plate shape between the first connection portion 162 and the second connection portion 163. The first connection part 162 is exposed to the outside of the end plate 22. The first connection part 162 is disposed on the upper surface 122 r of the end plate 122. The first bus bar 161 passes through the inside of the end plate 122 from the first connecting portion 162 and penetrates the lower surface 122 s of the end plate 122. The first bus bar 161 is bent outside the end plate 122, and extends to the second connection portion 163 while passing directly below the fixing bracket 151. The second connection portion 163 is superimposed on the fixed bracket 151 in the vertical direction.

  The first bus bar 161 is electrically connected to the unit cell 21 of each battery stack of the first battery stack 112A and the second battery stack 112B.

  The first battery stack 112 </ b> A includes a first bus bar 161 </ b> A as the first bus bar 161. The first bus bar 161A (more specifically, the first connection portion 162 of the first bus bar 161A) is connected to the positive terminal 24p of the unit cell 21 in the first battery stack 112A via the inter-cell bus bar 25. . The second battery stack 112 </ b> B has a first bus bar 161 </ b> B as the first bus bar 161. The first bus bar 161B (more specifically, the first connection portion 162 of the first bus bar 161B) is connected to the negative electrode terminal 24n of the unit cell 21 in the second battery stack 112B via the inter-cell bus bar 25. .

  Case body 131 corresponds to case body 31 in the first embodiment. Case body 131 has bottom wall 132 corresponding to bottom wall 32 in the first embodiment. The case body 131 is provided with a groove 136, a groove 137, and a groove 138. The groove 136, the groove 137, and the groove 138 are recessed from the bottom wall 132 to form a groove shape.

  The groove 136 extends linearly in the direction in which the first battery stack 112A and the second battery stack 112B are arranged. The groove part 137 and the groove part 138 extend in a direction orthogonal to the groove part 136. The groove portion 137 intersects with one end of the groove portion 136 immediately below the fixing bracket 151A. The groove 138 intersects with the other end of the groove 136 just below the fixed bracket 151B. The groove 136, the groove 137, and the groove 138 have an H shape when the bottom wall 132 is viewed from above.

  The second connection portion 163 of the first bus bar 161A is inserted into the groove portion 137. The second connection portion 163 of the first bus bar 161B is inserted into the groove portion 138.

  Battery pack 110 further includes a second bus bar 141. Second bus bar 141 corresponds to second bus bar 41 in the first embodiment.

  The second bus bar 141 extends linearly in the direction in which the first battery stack 112A and the second battery stack 112B are arranged. The second bus bar 141 is inserted into the groove 136. The second connection portion 163 of the first bus bar 161A is superimposed on one end of the second bus bar 141 from above. Thereby, the 2nd bus bar 141 is connected with the 2nd connection part 163 of the 1st bus bar 161A. The second connection portion 163 of the first bus bar 161B is superimposed on the other end of the second bus bar 141 from above. Thereby, the 2nd bus bar 141 is connected with the 2nd connection part 163 of the 1st bus bar 161B.

  The case body 131 is provided with a stud bolt 133 and a stud bolt 134. The stud bolt 133 is erected on the groove bottom at a position where the groove 136 and the groove 137 intersect. The stud bolt 133 passes through the second bus bar 141, the first bus bar 161A, and the fixing bracket 151A in order from the bottom. By fixing the nut 171 to the stud bolt 133 on the fixing bracket 151A, the fixing bracket 151A, the first bus bar 161A, and the second bus bar 141 are fastened together with the case body 131.

  The stud bolt 134 is erected on the groove bottom at a position where the groove 136 and the groove 138 intersect. The stud bolt 134 passes through the second bus bar 141, the first bus bar 161B, and the fixing bracket 151B in order from the lower side. By fixing the nut 172 to the stud bolt 134 on the fixing bracket 151B, the fixing bracket 151B, the first bus bar 161B, and the second bus bar 141 are fastened to the case body 131 together.

  The first battery stack 112A and the second battery stack 112B are electrically connected to each other in series by the first bus bar 161 and the second bus bar 141.

  According to the battery pack 110 in Embodiment 2 configured as described above, the effects described in Embodiment 1 can be similarly achieved.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  The present disclosure is applied to, for example, a battery pack for driving a vehicle.

  10, 110 battery pack, 12A, 112A first battery stack, 12B, 112B second battery stack, 21 cell, 22, 22A, 22B, 122, 122A, 122B end plate, 22r, 122r upper surface, 22s, 122s lower surface, 24n negative terminal, 24p positive terminal, 25 inter-cell bus bar, 27 bus bar insertion part, 28 restraint band, 31, 131 case body, 32, 132 bottom wall, 41, 141 second bus bar, 42 base part, 43, 62, 162 first 1 connection part, 44, 63, 163 2nd connection part, 51, 151, 151A, 151B fixing bracket, 61, 61A, 61B, 161, 161A, 161B first bus bar, 133, 134 stud bolt, 136, 137, 138 Groove, 171 and 172 nuts.

Claims (1)

A first battery stack and a second battery stack;
A case body for housing the first battery stack and the second battery stack;
Each of the first battery stack and the second battery stack is
A plurality of single cells stacked in one direction and electrically connected to each other;
A pair of end plates that are disposed on both sides of the plurality of unit cells and sandwich the plurality of unit cells in the stacking direction;
A first bus bar electrically connected to the unit cell;
At least a portion of the first bus bar is built in the end plate;
The case body is
An inner wall defining an internal space for accommodating the first battery stack and the second battery stack;
A battery pack comprising a second bus bar provided on the inner wall and electrically connecting the first bus bars between the first battery stack and the second battery stack.

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