JP2019067674A - Battery pack - Google Patents

Abstract

To provide a battery pack that can be miniaturized while suppressing the expansion of stacked battery cells.SOLUTION: A battery pack 1 according to the present invention includes a battery cell assembly 100 including a plurality of stacked battery cells 10, a first case 40 and a second case 50 internally supporting the battery cell assembly 100 in a mutually engaged state, and a restraint plate 30 covering the battery cell assembly 100 from one side in the stacking direction, and one end face of the battery cell assembly 100 is pressurized by the restraint plate 30, and the other end face abuts on the bottom surfaces of the first case 40 and the second case 50 engaged with each other.SELECTED DRAWING: Figure 10

Description

  The present invention relates to a battery pack.

  Conventionally, a chargeable / dischargeable battery module including a plurality of battery cells is known. For example, Patent Document 1 discloses a battery module in which a plurality of battery cells are disposed inside an upper frame and a lower frame in a state in which each battery cell is constrained by a cell cover. Patent Document 2 discloses a battery module in which both ends of a battery cell assembly composed of stacked battery cells are constrained. In any of the battery modules, expansion in the stacking direction of the plurality of battery cells is considered.

Patent No. 5154454 German Patent Application Publication No. 102013018400

  However, in the battery modules disclosed in Patent Documents 1 and 2 in which each battery cell is restrained by a cell cover or both ends of the battery cell assembly are restrained in order to suppress expansion, the case of the battery cell lamination direction Thickness may increase. Moreover, in such a battery module, the number of parts increases. Along with this, the cost also increases.

  An object of the present invention made in view of this point is to provide an assembled battery which can be miniaturized while suppressing the expansion of the stacked battery cells.

In order to solve the above-mentioned subject, an assembled battery concerning one embodiment of the present invention is:
A battery cell assembly comprising a plurality of battery cells stacked;
A first case and a second case that internally support the battery cell assembly in a mutually engaged state;
A constraining plate covering the battery cell assembly from one of the stacking directions;
Equipped with
The one end face of the battery cell assembly is pressurized by the restraint plate, and the other end face abuts on the bottom surfaces of the engaged first case and the second case.

  According to one embodiment of the present invention, it is possible to provide an assembled battery that can be miniaturized while suppressing the expansion of the stacked battery cells.

It is a perspective view showing the appearance of the group battery concerning a 1st embodiment of the present invention. It is a disassembled perspective view for every component inside the assembled battery shown in FIG. It is a figure which shows the battery cell single-piece | unit of FIG. It is a figure which shows the restraint board single-piece | unit of FIG. It is a figure which shows the 1st case single-piece | unit of FIG. It is a figure which shows the 2nd case single-piece | unit of FIG. It is a schematic diagram which shows the process for assembling an assembled battery. It is the schematic diagram which showed the mode inside the 1st case at the time of the 3rd process of FIG. 7, and a 4th process, and a 2nd case. It is the figure which expanded the broken-line enclosure part of FIG. It is a figure which shows the assembled battery accommodated in the housing | casing. It is a perspective view which shows the external appearance of the assembled battery which concerns on 2nd Embodiment of this invention. It is a top view which shows the battery cell single-piece | unit of FIG. It is a figure which shows the 1st case single-piece | unit of FIG. It is a perspective view which shows the external appearance of the assembled battery which concerns on 3rd Embodiment of this invention. It is a figure which shows the fitting part of 1st case and 2nd case.

  Hereinafter, one embodiment will be described with reference to the accompanying drawings. Front, rear, left, right, and top and bottom directions in the following description are based on the directions of arrows in the drawings. Hereinafter, although the stacking direction of the plurality of battery cells 10 will be described as the vertical direction as an example, the present invention is not limited to this. The stacking direction of the plurality of battery cells 10 may coincide with any other direction.

First Embodiment
FIG. 1 is a perspective view showing an appearance of a battery assembly 1 according to a first embodiment of the present invention. FIG. 2 is an exploded perspective view of each component in the battery assembly 1 shown in FIG. The assembled battery 1 includes six battery cells 10, insulating sheets 20, a restraint plate 30, a first case 40, and a second case 50 as large components.

  Six battery cells 10 are stacked in the vertical direction. Hereinafter, the six stacked battery cells 10 will be described as battery cells 10a, 10b, 10c, 10d, 10e, and 10f, respectively, from the lower side toward the upper side. When not distinguishing each battery cell, it describes collectively as the battery cell 10. FIG. Each battery cell 10 has two outer surfaces 11 each formed by a front surface and a rear surface substantially parallel to the vertical direction. Each battery cell 10 has a pair of electrode tabs 12p and 12n protruding in opposite directions from the two outer surfaces 11 along a direction perpendicular to the stacking direction, in particular, in the front-rear direction. Each battery cell 10 is stacked in a state in which one set of electrode tabs 12p and 12n is disposed along the front-rear direction.

  The insulating sheet 20 is formed substantially in the shape of a flat plate from an electrically insulating material such as polyethylene (PE) or polypropylene (PP) resin. Insulating sheet 20 is arranged to abut on the upper surface of battery cell 10 f located at the upper end of stacked battery cells 10. The insulating sheet 20 is provided to ensure electrical insulation between the restraint plate 30 in contact with the top surface of the assembled battery 1 and the battery cells 10 inside the assembled battery 1.

  The restraint plate 30 is disposed to abut on the top surface of the insulating sheet 20. The restraint plate 30 is fixed to the upper surfaces of the engaged first case 40 and second case 50 by an appropriate method such as screwing. For example, the restraint plate 30 is provided with holes 31 formed at the four corners at two screw holes 41 provided at the left and right ends of the front end of the first case 40 and at the left and right ends of the rear end of the second case 50. By screwing in accordance with the two screw holes 51, the first case 40 and the second case 50 engaged with each other are fixed. The restraint plate 30 clamps the battery cell 10 between the first case 40 and the second case 50 in a state in which the outer surface 13 perpendicular to the stacking direction formed by the upper surface and the lower surface of each battery cell 10 is restrained. At the same time, the restraint plate 30 supports the battery cell 10.

  The first case 40 and the second case 50 internally support the stacked battery cells 10 in a state where they are engaged with each other. That is, the stacked battery cells 10 are mounted on the bottom surface 40 a of the first case 40 and the bottom surface 50 a of the second case 50. The first case 40 and the second case 50 engaged with each other have an opening O facing the bottom and configured on the top. The connection surface S1 of the first case 40 and the second case 50 is substantially parallel to the outer surface 11 of the battery cell 10 on the electrode tab 12p or 12n side. That is, the connection surface S1 is parallel to the vertical direction. Thus, the first case 40 and the second case 50 are engaged or separated along the projecting direction of the electrode tabs 12 p and 12 n of the battery cell 10.

  Note that among the stacked battery cells 10, the battery cells 10 adjacent to each other may be adhered and fixed by an adhesive or an adhesive such as a double-sided tape. For example, the battery cells 10 adjacent to each other may be adhered and fixed by an arbitrary method such as applying an adhesive to the upper surface of each battery cell 10. Similarly, the battery cells 10f and the insulating sheets 20 may be adhered and fixed by an adhesive. Furthermore, the insulating sheet 20 and the restraint plate 30 may be similarly adhered and fixed by an adhesive.

  FIG. 3 is a view showing the battery cell 10 of FIG. 2 alone. FIG. 3A is a top view of the battery cell 10. FIG. 3 (b) is a side view of the battery cell 10. FIG. 3 shows a battery cell 10b arranged as shown in FIG. 2 as an example. The other battery cells 10 are also configured in the same manner as the battery cells 10b shown in FIG.

  Battery cell 10 is formed in a substantially flat plate shape in top view. The exterior member 14 of the battery cell 10 is formed of a laminate film. The outermost layer of the exterior member 14 is made of resin in order to ensure electrical insulation. The upper and lower surfaces of the exterior member 14 constitute the outer surface 13. The outer surface 11 protrudes outward by one step in the central portion than the left and right end portions. That is, the outer surface 11 is formed in a convex shape in top view. An electrode tab 12p or 12n is provided to project from a portion of the outer surface 11 that protrudes outward by one level. The electrode tabs 12p and 12n are normally provided in a flat plate shape, but in order to be in contact with the electrode tabs and the like of other battery cells 10 adjacent in the vertical direction, they are substantially L-shaped in a side view They are bent symmetrically to each other. For example, the electrode tab 12p linearly protrudes outward in the front-rear direction, and then bends downward. The electrode tab 12 n linearly protrudes outward in the front-rear direction, and then bends upward. Hereinafter, as one example, the electrode tab 12p bent downward is described as a positive electrode terminal, and the electrode tab 12n bent upward is described as a negative electrode terminal, but the invention is not limited thereto. The electrode tabs 12p and 12n may be configured such that the roles of the positive electrode and the negative electrode are reversed.

  FIG. 4 is a view showing the restraint plate 30 of FIG. 2 alone. FIG. 4A is a perspective view of the restraint plate 30 as viewed from above. FIG. 4 (b) is a cross-sectional view taken along the line II in FIG. 4 (a).

  The restraint plate 30 is preferably made of any rigid material. For example, the restraint plate 30 is preferably made of only a metal material. It is not limited to this, Restraint board 30 may be constituted by metal material or resin material by which electric insulating materials, such as PET resin, were given to the surface. The restraint plate 30 is formed in a substantially flat plate shape. The restraint plate 30 has a substantially rectangular recess 32 formed substantially in the center and recessed one step in the vertical direction. The four holes 31 are provided so as to protrude from the four corners of the outer edge of the restraint plate 30 surrounding the recess 32. The surface of the recess 32 is, for example, formed in a straight line so as to be substantially parallel to the surface of the outer edge portion of the restraint plate 30. The surface of the recess 32 is not limited to such a configuration, and may be formed as, for example, a linear or curved inclined surface that protrudes further inward toward the central portion. The assembled battery 1 can firmly fix the internal battery cell 10 by pressurization by the recess 32. The restraint plate 30 is not limited to the configuration like the recess 32. For example, the restraint plate 30 has a linear or curved inclined surface such that the surface of the restraint plate 30 gradually protrudes inward from the outer edge toward the center without the recess 32. May be formed. In addition, the restraint plate 30 may have at least one rib, for example, protruding on the lower surface of the central portion instead of the recess 32.

  FIG. 5 is a view showing the first case 40 of FIG. 2 alone. FIG. 5A is an enlarged perspective view of a part of the front surface of the first case 40 in top view. FIG. 5B is a perspective view of the first case 40 in a rear view and an enlarged view of two dashed line encircling portions. FIG. 5C is a rear view of the first case 40 and an enlarged view of a portion surrounded by a broken line thereof.

  The first case 40 is made of a metal material or a resin material on the surface of which an electrically insulating material such as PET resin is applied. The first case 40 may be made of any rigid material. The front center portion of the first case 40 is formed to project outward by one step. At the front center portion, four window portions 42 penetrating the front surface are extended in a substantially rectangular shape along the left-right direction. The window portion 42 is formed such that one half in the left-right direction is wider in the vertical direction than the other half. The window portion 42 is formed to be smaller than the end surfaces S2 of the electrode tabs 12p and 12n of the battery cell 10. The tip surfaces S2 of the electrode tabs 12p and 12n are the outer surfaces of the vertically bent portions (see FIG. 3B). The four windows 42 are arranged in a line along the vertical direction, with the positions of the left and right end portions and the left and right positions of the wide half portions aligned. Further, jig insertion holes 43 are formed on the left and right side surfaces of the front center portion of the first case 40. The jig insertion holes 43 are formed in pairs at substantially the same height positions as the windows 42 corresponding to the four windows 42 respectively. That is, the pair of jig insertion holes 43 are formed at substantially the same height position on the left and right sides of the front center portion of the first case 40.

  The first case 40 has an electrode tab 12 p or 12 n protruding from the outer surface 11 of the battery cell 10 or an abutment portion 44 that abuts on the outer surface 11. For example, the contact portion 44 is preferably constituted by the first inner wall 44a of the first case 40 to which the electrode tab 12p or 12n of the battery cell 10 faces when the battery cell 10 is inserted into the first case 40. It is. That is, the first inner wall 44 a is configured by the surface of the back surface of the front center portion of the first case 40 on which the window portion 42 is formed. In this case, when the six battery cells 10 are inserted into the first case 40, the front end surface S2 of the electrode tab 12p or 12n abuts on the first inner wall 44a.

  The first case 40 has a second inner wall 44 b located on the back side of the jig insertion hole 43 and formed one step inner than the first inner wall 44 a. The contact portion 44 may be configured by the second inner wall 44 b. In this case, when the six battery cells 10 are inserted into the first case 40, a central portion of the outer surface 11 that protrudes one step outward from the left and right end portions abuts on the second inner wall 44b.

  The first case 40 has a third inner wall 44c formed one step further inward than the second inner wall 44b. The contact portion 44 may be configured by the third inner wall 44c. In this case, when the six battery cells 10 are inserted into the first case 40, the left and right end portions of the outer surface 11 recessed one step inwardly from the central portion abut the third inner wall 44c.

  As described above, the positioning of each battery cell 10 is performed by bringing the corresponding portion into contact with the contact portion 44 of the first case 40 with reference to the electrode tabs 12 p or 12 n or the outer surface 11. The contact portion 44 is located near the window portion 42. More specifically, the contact portion 44 is formed to be located at the same front end as the front central portion in which the window 42 is formed in the first case 40. With the above configuration, the battery assembly 1 can be accurately positioned when welding the electrode tabs 12p and 12n of the adjacent battery cells 10.

  The first case 40 is provided so as to protrude inward from the first inner wall 44a, and further includes a guide portion 45 for guiding the electrode tab 12p or 12n toward the first inner wall 44a when the battery cell 10 is inserted. At least one guide portion 45 is provided to project from the first inner wall 44a. The first case 40 further includes a first insulating portion 46 a that protrudes inward from the first inner wall 44 a and electrically insulates the electrode tabs 12 p and 12 n adjacent in the stacking direction of the battery cells 10 from each other. A total of three first insulating portions 46 a are provided between the four window portions 42, one each. The front-rear position of the rear end of the first insulating portion 46a is the same as that of the second inner wall 44b. That is, the rear surface of the first insulating portion 46a and the second inner wall 44b are flush with each other.

  Each of the guide portions 45 is extended on the upper and lower surfaces of the first insulating portion 46 a so as to protrude in the vertical direction in the front-rear direction. As an example, four guide portions 45 are extended on the upper surface of each first insulating portion 46a. Each of them is preferably equally spaced in the left-right direction. Similarly, four guide portions 45 are extended on the lower surface of each first insulating portion 46a. Each of them is preferably equally spaced in the left-right direction. The guide portions 45 respectively formed on the upper and lower surfaces of the first insulating portion 46a may be disposed at the same lateral position, or may be disposed at different lateral positions.

  The guide portion 45 may have a tapered portion 45a that tapers in a direction away from the first inner wall 44a inward. For example, although the amount of protrusion from the first insulating portion 46a in the front half of the guide portion 45 is constant, the amount of protrusion from the first insulating portion 46a in the rear half of the guide portion 45 is , May decrease gradually inward. For example, the tapered shape of the tapered portion 45a may be linear or may be a gently curved shape. Thus, the separation width of the adjacent guide portions 45 in the state of being separated in the vertical direction increases as it goes inward. With the configuration of the tapered portion 45 a as described above, the assembled battery 1 can further improve the insertability of the battery cell 10 into the first case 40.

  The first case 40 has four accommodating portions 47 in which the back of the front central portion projecting outward by one step is divided in the vertical direction by the three first insulating portions 46 a. That is, each accommodation portion 47 accommodates the electrode tabs 12p and 12n arranged at the corresponding upper and lower positions. Hereinafter, the four accommodating portions 47 are respectively described as accommodating portions 47a, 47b, 47c, and 47d from the lower side toward the upper side. When not distinguishing each accommodating part, it describes collectively as the accommodating part 47. FIG. One window portion 42 is disposed at each of the front ends of the housing portions 47a to 47d.

  The first case 40 has a second insulating portion 46 b protruding inward from both inner side surfaces in the left-right direction. The second insulating portion 46b insulates the adjacent battery cells 10 from each other in a stacked state. For example, a total of five second insulating portions 46 b are arranged one by one between each of the six stacked battery cells 10. For example, the second insulating portions 46b are arranged at the same front-rear width and the same front-rear position along the stacking direction of the six battery cells 10, that is, the top-bottom direction. The second insulating portion 46b also functions as a guide when the battery cell 10 is inserted into the first case 40.

  FIG. 6 is a view showing the second case 50 of FIG. 2 alone. FIG. 6A is a perspective view from the top view in which a part of the rear surface of the second case 50 is enlarged. FIG. 6B is a perspective view of the second case 50 in a rear view and an enlarged view of two dashed line encircling portions. FIG. 6C is a rear view of the second case 50 and an enlarged view of a portion surrounded by a broken line thereof.

  The second case 50 is configured in the same manner as the first case 40, and has a screw hole 51, a window 52, a jig insertion hole 53, a first inner wall 54a, a second inner wall 54b, a third inner wall 54c, a guide 55, and a taper. A portion 55a, a first insulating portion 56a, a second insulating portion 56b, and a housing portion 57 are provided. The above description of the first case 40 is similarly applied to the corresponding components of the second case 50. Below, points different from the first case 40 regarding the second case 50 will be mainly described.

  Three windows 52 of the second case 50 are formed so as to be located between the corresponding windows 42 of the first case 40 in the vertical direction. More specifically, the four windows 42 are described as windows 42a, 42b, 42c, and 42d from the lower side to the upper side, and the three windows 52 are each from the lower side to the upper side. It is written as windows 52a, 52b and 52c. In this case, the window 52a is located between the window 42a and the window 42b in the vertical direction. The window 52 b is located between the window 42 b and the window 42 c in the vertical direction. The window 52 c is located between the window 42 c and the window 42 d in the vertical direction.

  As an example, the wide half of the window 52 may be formed on the same side as the wide half of the window 42 in the left-right direction. That is, when the wide half of the window 42 is formed on the left side as an example as shown in FIG. 5, the wide half of the window 52 is formed on the left as shown in FIG. .

  Two first insulating portions 56 a are provided between the three window portions 52, one each, in total. Three housing portions 57 are provided in a state in which the back portion of the rear surface central portion that protrudes one step outward is divided in the vertical direction by the two first insulating portions 56a. That is, each accommodation portion 57 accommodates the electrode tabs 12p and 12n arranged at the corresponding upper and lower positions. Hereinafter, the three accommodating portions 57 are respectively described as accommodating portions 57a, 57b and 57c from the lower side toward the upper side. When not distinguishing each accommodating part, it describes collectively as the accommodating part 57. FIG. The guide portion 55 is similarly extended to the bottom surface of the housing portion 57a and the ceiling surface of the housing portion 57c. As an example, four guide portions 55 are extended on each surface.

  FIG. 7 is a schematic view showing a process for assembling the battery assembly 1. 7 (a) to 7 (d) are schematic views respectively showing representative first to fourth steps for assembling the battery assembly 1. As shown in FIG. FIG. 8 is a schematic view showing the inside of the first case 40 and the second case 50 in the third and fourth steps of FIG. 7. FIG. 8 (a) is an enlarged view of a part of a cross section taken along the line II-II in FIG. 7 (c). FIG. 8 (b) is an enlarged view of a part of a cross section taken along the line III-III in FIG. 7 (d). FIG. 9 is an enlarged view of a portion enclosed by a broken line in FIG. Fig.9 (a) is the figure which expanded the broken-line enclosure part R1 of Fig.8 (a). FIG.9 (b) is the figure which expanded the broken-line enclosure part R2 of Fig.8 (a).

  In the first step shown in FIG. 7A, the six battery cells 10 and the insulating sheets 20 to be stacked are inserted into the first case 40 one by one in order from the lower side. The six battery cells 10 are inserted into the first case 40 with the respective electrode tabs 12p and 12n bent. At this time, each battery cell 10 is positioned with its corresponding portion abutting on the contact portion 44 of the first case 40 with reference to the electrode tab 12 p or 12 n or the outer surface 11. That is, among battery cells 10, the outer surface 11 side on which electrode tabs 12p or 12n are formed is used for positioning battery cells 10, particularly electrode tabs 12p or 12n with respect to the first case 40. In the second step shown in FIG. 7 (b), the second case 50 is fitted from the rear to the first case 40 holding the battery cell 10 and the insulating sheet 20. At the same time, the total plus bus bar 60a and the total minus bus bar 60b are temporarily fixed to the first case 40. In the third step shown in FIG. 7C, the corresponding jig 70a is inserted from the jig insertion hole 43 of the first case 40, and the electrode tabs 12p and 12n are fixed in the first case 40. As an example, the electrode tabs 12p and 12n are fixed in a state of being in contact with the first inner wall 44a by the jig 70a. Thereafter, the electrode tabs 12p and 12n, the electrode tabs 12p and the total plus bus bar 60a, and the electrode tabs 12n and the total minus bus bar 60b are respectively welded by an appropriate method such as laser welding. For example, in the case of laser welding, a laser for welding is irradiated to the welding spot through the window portion 42. In the fourth step shown in FIG. 7D, the corresponding jig 70b is inserted from the jig insertion hole 53 of the second case 50 to fix the electrode tabs 12p and 12n. Thereafter, the electrode tabs 12p and 12n are welded to each other by a suitable method such as laser welding. For example, in the case of laser welding, a laser for welding is irradiated to the welding spot through the window 52.

  After the fourth step shown in FIG. 7D, the restraint plate 30 is fixed to the upper surfaces of the engaged first case 40 and second case 50 by an appropriate method such as screwing. Thus, the assembly of the battery assembly 1 is completed.

  According to the above process, as shown in FIG. 8, the electrode tabs 12 p and 12 n of each battery cell 10 are accommodated in the accommodation portion 47 of the first case 40 and the accommodation portion 57 of the second case 50. In this state, the six battery cells 10 are stacked so that the electrode tabs 12p and 12n of the adjacent battery cells 10 are alternately arranged in the front and rear.

  For example, as shown to Fig.8 (a), the electrode tab 12p of the battery cell 10a is arrange | positioned at the accommodating part 47a. In the housing portion 47b, the electrode tab 12n of the battery cell 10b disposed adjacent to the top of the battery cell 10a is disposed. Similarly, the electrode tab 12p of the battery cell 10c disposed adjacent to the top of the battery cell 10b is disposed in the housing portion 47b. Similarly, in the housing portions 47c and 47d, the electrode tabs 12p and 12n on the front side of the battery cells 10d, 10e and 10f are alternately arranged. As a result, one, two, two, and one electrode tabs are provided in the four accommodating portions 47 of the first case 40 with the electrode tabs 12p and 12n alternately arranged from the lower side to the upper side. Be housed.

  For example, as shown in FIG. 8B, the electrode tab 12n of the battery cell 10a is disposed in the housing portion 57a. The electrode tab 12p of the battery cell 10b disposed adjacent to the top of the battery cell 10a is also disposed in the housing portion 57a. Similarly, the electrode tabs 12p and 12n on the rear surface side of the battery cells 10c, 10d, 10e and 10f are alternately arranged in the housing portions 57b and 57c. As a result, in the three accommodating portions 57 of the second case 50, the electrode tabs 12p and 12n are alternately arranged from the lower side to the upper side. Each accommodation portion 57 accommodates two electrode tabs 12p and 12n.

  As mentioned above, the electrode tabs 12p and 12n of each battery cell 10 are respectively connected with the electrode tab which has the opposite polarity of the adjacent battery cell 10 by bending in the up-down direction mutually. Finally, the six battery cells 10 are connected in series with one another.

  As shown in FIG. 9A, the housing portion 47d at the upper end of the first case 40 houses the electrode tab 12n of one battery cell 10f. The end of the total minus bus bar 60b is also accommodated in the accommodation portion 47d. As one example, the tip end face S2 of the electrode tab 12n faces the first inner wall 44a, and the back side of the tip end face S2 faces the end of the total minus bus bar 60b. In other words, the first inner wall 44a, the tip of the electrode tab 12n, and the end of the total minus bus bar 60b are arranged in this order from the outside to the inside. In this state, when the jig 70a is inserted in the third step shown in FIG. 7C, the respective surfaces abut each other.

  As shown in FIG. 8A, the housing portion 47a at the lower end of the first case 40 houses the electrode tab 12p of one battery cell 10a and also houses the end of the total plus bus bar 60a. . The above description with respect to FIG. 9A also applies to the relationship between the electrode tab 12p in the housing portion 47a and the total plus bus bar 60a.

  As shown in FIG. 9 (b), the electrode tabs 12 p and 12 n of the two battery cells 10 are accommodated in the central two accommodation parts 47 b and 47 c of the first case 40 in a superimposed state. As one example, the tip end face S2 of the electrode tab 12n faces the first inner wall 44a, and the back side of the tip end face S2 faces the tip end face S2 of the electrode tab 12p. In other words, the first inner wall 44a, the tip of the electrode tab 12n, and the tip of the electrode tab 12p are arranged in this order from the outside to the inside. In this state, when the jig 70a is inserted in the third step shown in FIG. 7C, the respective surfaces abut each other.

  FIG. 10 is a view showing the battery assembly 1 housed in the housing 80. As shown in FIG. FIG. 10A is a perspective view from the top view showing a cross section of the case 80 supporting the assembled battery 1. FIG. 10 (b) is a cross-sectional view taken along the line IV-IV in FIG. 10 (a). FIG.10 (c) is the figure which expanded the dashed-line enclosed part of FIG.10 (b).

  The housing 80 is preferably made of a metal material such as aluminum. Without being limited to this, the housing 80 may be made of any rigid material. For example, the housing 80 may be made of a metal material or a highly rigid resin material to which an electrically insulating material such as PET resin is applied on the surface.

  The battery assembly 1 is fixed to the inside of the housing 80 by an appropriate method such as screwing. More specifically, the assembled battery 1 is housed inside the housing 80 in a state where the bottom surface 40 a of the first case 40 and the bottom surface 50 a of the second case 50 abut on the bottom surface 80 a of the housing 80. At this time, the bottom surface 80 a of the housing 80 functions as a constraining member for constraining the stacked battery cells 10 from the lower side, similarly to the upper constraining plate 30. That is, the stacked battery cells 10 are indirectly restrained by the bottom surface 80 a by being in contact with the bottom surface 40 a of the first case 40 and the bottom surface 50 a of the second case 50 in contact with the bottom surface 80 a. Without being limited to such a configuration, for example, if the bottom surface 40a of the first case 40 and the bottom surface 50a of the second case 50 have sufficient rigidity, they can function as restraint members by themselves. For example, the bottom surface 80a may not be in contact with the bottom surface 40a and the bottom surface 50a.

  As shown in FIG. 10, the fixing portion F of the first case 40 and the second case 50 to the housing 80 is provided inside the bottom surface 80 a of the housing 80. That is, the fixing portion F is positioned above the bottom surface 80 a so as to be closer to the center of gravity of the battery cell assembly 100 including the stacked six battery cells 10.

  The fixing portion F may be configured, for example, as follows. That is, as an example, the two screw holes 41 of the first case 40 may penetrate from the upper surface to the lower surface of the first case 40. Similarly, the two screw holes 51 of the second case 50 may penetrate from the upper surface to the lower surface of the second case 50. On the other hand, in order to support the two screw holes 41 and the two screw holes 51, the housing 80 has support portions 81 protruding inward from the bottom surface 80a at positions corresponding to each. On the upper surface of the support portion 81, screw holes 81a for screwing with the screws inserted from above in the two screw holes 41 and the two screw holes 51 are screwed. For example, the first case 40 and the second case 50 may be fixed to the housing 80 by inserting a screw from above into the screw hole 41 and the screw hole 51 and screwing it with the screw hole 81 a. That is, the fixing portion F may be configured by the screw hole 41 or the screw hole 51 and the screw hole 81 a.

  As described above, the bottom surface of the assembled battery 1 is fixed in a state of being in contact with the bottom surface 80 a of the housing 80. Therefore, the bottom surface side of the battery assembly 1 is strongly restrained from below by the bottom surface 80 a of the housing 80. On the other hand, when the upper surface side of the assembled battery 1 is temporarily constituted only by the first case 40 and the second case 50 and the insulating sheet 20, the restraining force is weak compared to the bottom surface side. Therefore, in a state where the battery pack 1 is fixed to the housing 80, the restraint plate 30 is fixed to the first case 40 and the second case 50 so as to cover the battery cell assembly 100 from one side in the stacking direction, that is, from above. ing. As described above, the restraint plate 30 has the recess 32 that is recessed one step toward the top surface of the battery cell assembly 100. At this time, the insulating sheet 20 is disposed between the restraint plate 30 and the upper surface of the battery cell assembly 100. Insulating sheet 20 abuts on recess 32 of restraint plate 30 and the upper surface of battery cell assembly 100. On the other hand, the bottom surface 40 a of the first case 40 and the bottom surface 50 a of the second case 50 abut on the bottom surface 80 a of the housing 80. That is, while the upper surface of battery cell assembly 100 is pressed from above by restraint plate 30, the bottom surface 40a of first case 40 and the bottom surface 50a of second case 50 are in contact with the lower surface of battery cell assembly 100. , Supported by the bottom surface 80 a of the housing 80. Thereby, the vertical direction position of each battery cell 10 is regulated. At this time, the gas generated inside the battery cell 10 due to deterioration with time becomes easy to collect on the outer periphery of the battery cell 10 due to pressurization in the stacking direction. That is, the internal gas is collected at a location away from the electrode formed at the center.

  Generally, there is a correlation between the battery characteristics of the battery cell 10 and the pressure in the stacking direction of the battery cell 10. That is, by applying a predetermined pressure, the electrode spacing in the battery cell 10 is stabilized, so the internal resistance is reduced, and the battery characteristics of the battery cell 10 are improved. On the other hand, when the pressure is excessively applied, the chemical reaction itself in the battery cell 10 is inhibited, and the battery characteristics are degraded. Therefore, at the time of assembly of the battery assembly 1, it is preferable to fix the restraint plate 30 so that pressure is applied within a predetermined pressure range so as to obtain stable and good battery characteristics over time. As a result, even if the battery cell 10 expands with time deterioration and the pressure in the stacking direction of the battery cell 10 increases due to the reaction, an optimal pressure value capable of maintaining the battery characteristics can be secured.

  The assembled battery 1 according to the first embodiment as described above can be accurately positioned when welding the electrode tabs 12p and 12n of the adjacent battery cells 10. That is, the electrode tabs 12p or 12n or the outer surface 11 to be the reference of positioning, and the portion to be welded are arranged close to each other. Thereby, the assembled battery 1 can improve the positioning accuracy of the electrode tabs 12p and 12n at the time of welding as compared with the case where the portion to be welded to the reference of positioning is disposed on the outer surface of the battery cell in different directions. In particular, by using the contact portion 44 as the first inner wall 44a, the battery pack 1 can arrange the electrode tabs 12p or 12n serving as a reference for positioning and the welding portion substantially at the same position. Thereby, the positioning accuracy of the electrode tabs 12p and 12n at the time of welding is further improved. Thus, the battery assembly 1 can simplify the welding process by simplifying the welding process of the electrode tabs 12p and 12n. Thereby, the battery pack 1 can also contribute to the improvement of the reliability as a product.

  The battery assembly 1 can improve the insertability of the battery cell 10 into the first case 40 and the second case 50 by having the guide portions 45 and 55 and the second insulating portions 46 b and 56 b. The effect is also obtained by the configuration of at least one of the guide portions 45 and 55 and the second insulating portions 46 b and 56 b. When all these configurations are provided, the effect appears most notably. Further, by providing the tapered portions 45 a and 55 a in the guide portions 45 and 55 respectively, the assembled battery 1 can further improve the insertability. That is, the battery assembly 1 prevents the electrode tabs 12p and 12n from contacting and deforming the inner surface of the first case 40 or the second case 50 at the time of insertion, thereby reliably holding the electrode tabs 12p and 12n. It can be accommodated in 57. In particular, the formation of the tapered portions 45a and 55a increases the distance between the guide portions 45 and 55 in the vertical direction toward the inner side, thereby avoiding the interference between the electrode tabs 12p and 12n and the inner wall of the case during insertion. It becomes easy to do. Further, in the assembled battery 1, the manufacturing process of the first case 40 and the second case 50 can be simplified by the same position and number of the guide portions 45 and 55 in the left-right direction. That is, the battery assembly 1 can contribute to the improvement of the productivity.

  The battery assembly 1 can ensure electrical insulation in the stacking direction of the adjacent battery cells 10 by providing the first insulating portions 46 a and 56 a and the second insulating portions 46 b and 56 b. That is, not only in the initial state but also when the battery cell 10 expands due to deterioration with time and the upper and lower positions of the electrode tabs 12p and 12n change, the insulation can be maintained.

  In the assembled battery 1, the outer surface 13 perpendicular to the stacking direction of the battery cells 10 is restrained by the restraining plate 30 to prevent the battery from being used during charging, discharging or aging with use of the assembled battery 1. Expansion of the cells 10 in the stacking direction can be suppressed. By forming the restraint plate 30 of a metal material, the assembled battery 1 can improve its rigidity and effectively suppress the expansion of the battery cell 10.

  In the assembled battery 1, since the insulating sheet 20 and the restraint plate 30 are provided one by one only in one of the stacked battery cells 10, the number of parts can be reduced and productivity can be improved. As described above, the assembled battery 1 is advantageous in terms of the number of parts and productivity, as compared with the conventional assembled battery in which a cell cover is provided for each battery cell to protect each battery cell, for example. That is, the battery assembly 1 can contribute to the improvement of the productivity and the cost reduction by the simplified configuration. In addition, the battery cells 10, the battery cells 10 and the insulating sheets 20, and the insulating sheets 20 and the restraint plates 30 are fixed to each other by an adhesive, whereby the resistance of the assembled battery 1 to vibration or impact is improved. For example, when mounted on a vehicle, the battery pack 1 can prevent relative displacement between components due to vibration or impact during traveling. As described above, the assembled battery 1 can firmly fix the internal components to each other to prevent damage to the internal components due to vibration or impact.

  The assembled battery 1 can be miniaturized and reduced in height while suppressing the expansion of the stacked battery cells 10. That is, in the assembled battery 1, the battery cell assembly 100 is pressed from the one side in the stacking direction by the one restraint plate 30, and at the same time, the bottom surface is the bottom surface 40 a of the first case 40 and the bottom surface 50 a of the second case 50. By bringing the battery cells into contact with each other, expansion of the battery cells 10 in the stacking direction can be suppressed. At the same time, since the number of restraint plates 30 used is one, the assembled battery 1 can be miniaturized, reduced in height, and reduced in weight as compared with a conventional battery module provided with a plurality of restraint plates. Similarly, the battery assembly 1 can also contribute to the reduction of the number of parts and the cost.

  The battery pack 1 can suppress the deterioration of the first case 40 and the second case 50 by providing the opening O. For example, if the restraint plate 30 is disposed directly on the upper surfaces of the first case 40 and the second case 50 without providing the opening O, the restraint plate 30 directly presses these cases, so the case is deformed. Deterioration is promoted. Therefore, the battery assembly 1 can prevent damage to the case due to such deterioration with time.

  The battery assembly 1 can be appropriately pressurized to the central portion of the outer surface 13 of the battery cell 10 perpendicular to the stacking direction by the configuration of the recess 32 of the restraint plate 30. Thereby, the assembled battery 1 can suppress the expansion of the battery cell 10 in the stacking direction. In addition, since the battery pack 1 can properly hold the battery cell assembly 100 inside the first case 40 and the second case 50 by pressing with the restraint plate 30, the holding reliability is also improved. That is, the battery pack 1 can fix the battery cell assembly 100 more firmly by the pressurization by the recess 32. The battery assembly 1 can stabilize the internal resistance in the battery cell 10 by pressurizing with a pressure in an optimal range that can maintain good battery characteristics. Furthermore, since the assembled battery 1 releases the internal gas from the vicinity of the electrode to the outer periphery of the battery cell 10 by pressurization, deterioration of the battery cell 10 can be suppressed. That is, the assembled battery 1 suppresses the deterioration of the battery characteristics due to the presence of the internal gas between the electrodes. In particular, the battery assembly 1 is formed such that the surface of the recess 32 protrudes further inward toward the central portion, thereby more concentrating the pressure on the central portion of the outer surface 13 of the battery cell 10 Expansion of the battery cell 10 in the stacking direction can be suppressed more effectively. In this case, the battery pack 1 can also more efficiently collect the internal gas to the outer periphery of the battery cell 10.

  The battery assembly 1 can ensure electrical insulation between the restraint plate 30 and the internal battery cell 10 by the arrangement of the insulating sheet 20.

  Furthermore, the assembled battery 1 can further improve the supportability of the battery cell assembly 100 by bringing the bottom surface 40 a of the first case 40 and the bottom surface 50 a of the second case 50 into contact with the bottom surface 80 a of the housing 80. In particular, the assembled battery 1 has the restraint plate 30 on the upper surface side, and the bottom surface of the assembled battery 1 abuts on the bottom surface 80a of the housing 80, so the internal battery cell assembly 100 is strongly restrained from both the upper and lower directions. . Furthermore, the first case 40 and the second case 50 are less likely to be bent even when the battery cell assembly 100 is supported, due to the restraint in the vertical direction by the restraint plate 30 and the bottom surface 80 a. In other words, the deflection of the first case 40 and the second case 50 is restricted by the restraint plate 30 and the bottom surface 80a.

  The battery assembly 1 can fix the heavy load called the battery cell assembly 100 in a well-balanced manner by arranging the fixing portion F to be closer to the center of gravity of the battery cell assembly 100. For example, when the battery assembly 1 is mounted on a vehicle, the stress generated by vibration or impact during traveling is alleviated. Thereby, the assembled battery 1 can improve the reliability as a product. Further, the battery pack 1 can contribute to the reduction in height by the arrangement.

  The assembled battery 1 is a component such as an electrical component disposed outside the assembled battery 1 by forming the first case 40 and the second case 50 with a metal material or a resin material having an electrically insulating material applied on the surface. Thus, the electrical insulation between the battery cell 10 inside the assembled battery 1 can be secured.

  Similarly to the first case 40 and the second case 50, the battery assembly 1 can further improve the electrical insulation by forming the restraint plate 30 with a metal material or a resin material to which an electrical insulation material is applied. . Further, in such a case, the battery assembly 1 can be manufactured inexpensively by reducing the weight of the restraint plate 30, which can contribute to the weight reduction and cost reduction of the battery assembly 1 itself.

Second Embodiment
FIG. 11 is a perspective view showing the appearance of the battery assembly 1 according to the second embodiment of the present invention. FIG. 11A is a completed view of the battery assembly 1. FIG. 11 (b) is an exploded perspective view of the battery assembly 1. 12 is a top view showing the battery cell 10 of FIG. 11 alone. The assembled battery 1 according to the second embodiment is different from the first embodiment in that the electrode tabs 12p and 12n of the battery cell 10 are formed on the same surface. Hereinafter, the same components as those in the first embodiment are denoted by the same reference numerals. Moreover, the description is abbreviate | omitted and the point which is different from 1st Embodiment is mainly demonstrated.

  As shown in FIG. 12, the outer surface 11 of the battery cell 10 protrudes outward by one step more than the left and right end portions at the central portion of each of the two half portions along the left-right direction. That is, the outer surface 11 is formed such that two convex shapes are continuous in the left-right direction in top view. Electrode tabs 12p and 12n respectively project from two portions of the outer surface 11 that protrude outward by one level. The electrode tabs 12p and 12n protrude outward in a symmetrical manner so as to be substantially L-shaped. For example, the electrode tab 12p linearly projects forward and then bends downward. The electrode tab 12 n linearly protrudes forward and then bends upward.

  As shown in FIG. 11B, the six battery cells 10 are stacked so that the positions of the electrode tabs 12p and 12n in the left-right direction alternate between adjacent battery cells 10. Specifically, the electrode tab 12p is disposed on the right side of the outer surface 11 of the lowermost battery cell 10a, and the electrode tab 12n is disposed on the left side. Electrode tab 12n is disposed on the right side of outer surface 11 of battery cell 10b adjacent to the top of battery cell 10a, and electrode tab 12p is disposed on the left side. Electrode tabs 12p and 12n are similarly arranged for battery cells 10c, 10d, 10e and 10f.

  FIG. 13 is a view showing the first case 40 of FIG. 11 alone. FIG. 13A is a perspective view of the first case 40 in a rear view and an enlarged view of a portion surrounded by a broken line thereof. FIG. 13B is a rear view of the first case 40 and an enlarged view of a portion surrounded by a broken line thereof.

  On the front surface of the first case 40, four windows 421 penetrating the right half and three windows 422 penetrating the left half are extended in a substantially rectangular shape along the left-right direction. The window portion 421 and the window portion 422 are formed such that one half in the left-right direction is wider in the vertical direction than the other half. The four window portions 421 are arranged in a line along the vertical direction, with the positions of the left and right end portions and the left and right positions of the wide half portions aligned. Similarly, the three window portions 422 are arranged in a line along the vertical direction, with the positions of the left and right ends and the left and right positions of the wide half portions aligned.

  The three windows 422 are formed to be located between the corresponding windows 421 in the vertical direction. More specifically, the four windows 421 are described as windows 421a, 421b, 421c, and 421d from the bottom to the top, and the three windows 422 are from the bottom to the top, respectively. It is described as windows 422a, 422b and 422c. In this case, the window 422a is located between the window 421a and the window 421b in the vertical direction. The window 422 b is located between the window 421 b and the window 421 c in the vertical direction. The window 422c is located between the window 421c and the window 421d in the vertical direction. Also, as an example, the wide half of the window 421 and the wide half of the window 422 may be positioned on the central side of the front surface of the first case 40, respectively.

  The first case 40 has contact portions 44 that abut the electrode tabs 12 p and 12 n or the outer surface 11 protruding from the outer surface 11 of the battery cell 10. For example, the contact portion 44 is preferably constituted by the first inner wall 44a of the first case 40 where the electrode tabs 12p and 12n of the battery cell 10 face each other when the battery cell 10 is inserted into the first case 40. It is. That is, the first inner wall 44 a is formed by the surface of the back side of the front surface of the first case 40 on which the windows 421 and 422 are formed. In this case, when the six battery cells 10 are inserted into the first case 40, the tip surfaces S2 of the electrode tabs 12p and 12n abut on the first inner wall 44a.

  The first case 40 has a second inner wall 44b formed one step inner than the first inner wall 44a. The contact portion 44 may be configured by the second inner wall 44 b. In this case, when the six battery cells 10 are inserted into the first case 40, the central portions of the two half portions of the outer surface 11 that project one step outward beyond the left and right end portions form the second inner wall 44b. And abut.

  The first case 40 has a third inner wall 44c formed one step further inward than the second inner wall 44b. The contact portion 44 may be configured by the third inner wall 44c. In this case, when the six battery cells 10 are inserted into the first case 40, the central portion and the left and right end portions of the outer surface 11 are recessed one step inwardly from the central portions of the two half portions, It abuts on the third inner wall 44c.

  As described above, the positioning of each battery cell 10 is performed by bringing the corresponding portions into contact with the contact portions 44 of the first case 40 with reference to the electrode tabs 12 p and 12 n or the outer surface 11. Further, the contact portion 44 is located in the vicinity of the windows 421 and 422. More specifically, the contact portion 44 is formed at the same front end as the front surface of the first case 40 on which the windows 421 and 422 are formed.

  The first case 40 further includes a guide portion 45, a tapered portion 45a, and a first insulating portion 46a configured in the same manner as in the first embodiment. A total of five first insulating portions 46 a are provided between the four windows 421 and the three windows 422, one each.

  The first case 40 has four accommodating portions 471 and three accommodating portions 472 which are divided in the vertical direction by the three first insulating portions 46 a and the two first insulating portions 46 a on the back sides of the left and right half portions of the front surface. Have. That is, each of the accommodating portions 471 and 472 accommodates the electrode tabs 12p and 12n arranged at the corresponding upper and lower positions. Hereinafter, the four accommodating portions 471 are respectively described as accommodating portions 471a, 471b, 471c, and 471d from the lower side toward the upper side. The three accommodating portions 472 are respectively described as accommodating portions 472 a, 472 b and 472 c from the lower side to the upper side. When not distinguishing each accommodating part, it describes collectively as the accommodating parts 471 and 472. FIG. Window portions 421a to 421d are disposed at the front ends of the accommodation portions 471a to 471d, respectively. Windows 422a to 422c are disposed at the front end of the housings 472a to 472c, respectively.

  The first case 40 has a second insulating portion 46 b projecting inward from both inner side surfaces in the left-right direction to the third inner wall 44 c. The second insulating portion 46b insulates the adjacent battery cells 10 from each other in a stacked state.

  A jig insertion hole 43 is formed at the front end portions of the left and right side surfaces of the first case 40. The jig insertion holes 43 are formed in pairs at substantially the same height positions as the windows 421 and 422 corresponding to the seven windows 421 and 422, respectively.

  As shown in FIG. 11B, the second case 50 may have a second insulating portion 56b protruding substantially in a U-shape along the inner surface. The second insulating portion 56b may be formed, for example, only on the left and right side surfaces or only on the rear surface. The second insulating portion 56b insulates the adjacent battery cells 10 from each other in a stacked state. It is preferable that the same number of second insulating portions 56 b be arranged at the same position in the vertical direction as the second insulating portion 46 b of the first case 40.

  The second case 50 may have a guide 55 as in the first embodiment. In this case, for example, the guide portions 55 may be provided in a suitable arrangement and in number in at least one of the upper surface and the lower surface of the second insulating portion 56b formed on the rear surface.

  In the present embodiment, the windows 421 and 422 are concentrated on the front face, so that the fourth process described using FIG. 7 is not necessary in assembling the battery assembly 1. When assembly of assembled battery 1 is completed by the same steps as the first step to the third step described in FIG. 7, electrode tabs 12 p and 12 n of each battery cell 10 are accommodated in storage portions 471 and 472 of first case 40. Housed in In this state, the six battery cells 10 are stacked such that the electrode tabs 12p and 12n of the adjacent battery cells 10 are alternately arranged.

  For example, the electrode tab 12p of the battery cell 10a and the total plus bus bar 60a (not shown) are disposed in the housing portion 471a. In the housing portion 472a, the electrode tab 12n of the battery cell 10a and the electrode tab 12p of the battery cell 10b disposed adjacent to the top of the battery cell 10 are disposed. Similarly, in the housing portion 471b, the electrode tab 12n of the battery cell 10b and the electrode tab 12p of the battery cell 10c disposed adjacent to the top of the battery cell 10b are disposed. Similarly, the electrode tabs 12p and 12n are alternately arranged in the housing portions 472b, 471c, 472c, and 471d. In the housing portion 471d, in addition to the electrode tabs 12n of the battery cell 10f, a total minus bus bar 60b (not shown) is also disposed.

  The battery assembly 1 according to the second embodiment as described above exhibits the same effects as the effects described above in the first embodiment. In addition, in the battery assembly 1 according to the second embodiment, since the window portions 421 and 422 are concentrated on the front surface, the number of assembling steps can be reduced. Thereby, the assembled battery 1 can contribute to the improvement of productivity. Furthermore, the electrode tabs 12p and 12n of the battery cell 10 are formed only on the outer surface 11, and the rear portion of the battery cell 10 is flat, so that the front-rear width of the battery cell 10 is shortened by the electrode tab 12p or 12n. Along with this, the front-rear width of the second case 50 also becomes short, and the battery assembly 1 can contribute to the downsizing as a whole.

Third Embodiment
FIG. 14 is a perspective view showing the appearance of the battery assembly 1 according to the third embodiment of the present invention. The battery assembly 1 according to the third embodiment has, as shown in FIG. 14, a discharge unit for discharging the gas generated inside the battery cell 10 to the outside in addition to the configuration of the battery assembly 1 according to the first embodiment. It has 90. In addition, the assembled battery 1 may add the discharge part 90 to the structure of the assembled battery 1 which concerns on 2nd Embodiment. Hereinafter, the same components as those in the first embodiment and the second embodiment are denoted by the same reference numerals. Moreover, the description is abbreviate | omitted and it demonstrates mainly paying attention to the discharge part 90 different from 1st Embodiment and 2nd Embodiment.

  For example, one discharge unit 90 is provided on the left side surface of the second case 50. The discharge part 90 has the discharge tube 91 extended toward the exterior from the said side. The discharge part 90 may be provided on any of the outer surfaces of the first case 40 and the second case 50 other than the left side surface of the second case 50 as long as the internal gas can be discharged efficiently to the outside. Good. The discharge part 90 is not limited to one, You may be provided with two or more.

  Gas is generated inside the battery cell 10 with the deterioration with time. When the pressure of the internal gas exceeds a predetermined value, the internal gas is released from the peripheral end of the battery cell 10 to the outside. Exhaust unit 90 guides the internal gas emitted from battery cell 10 to the outside of assembled battery 1 through exhaust tube 91.

  The battery assembly 1 according to the third embodiment as described above exhibits the same effects as the above-described effects described in the first and second embodiments. In addition, the battery assembly 1 according to the third embodiment can improve the safety by guiding the internal gas to the outside by the discharge unit 90. In other words, the battery pack 1 can improve the reliability as a product.

  It will be apparent to those skilled in the art that the present invention can be realized in other predetermined forms other than the above-described embodiment without departing from the spirit or essential characteristics thereof. Thus, the foregoing description is illustrative and not restrictive. The scope of the invention is defined by the appended claims rather than by the foregoing description. Some of the changes that come within the scope of the equivalents are intended to be embraced therein.

  FIG. 15 is a view showing a fitting portion between the first case 40 and the second case 50. As shown in FIG. FIG. 15A is a perspective view showing the appearance of the battery assembly 1. FIG.15 (b) is the figure which expanded the dashed-line enclosed part of Fig.15 (a).

  For example, the first case 40 and the second case 50 are engaged with each other in a state in which the engagement claws E1 are formed on one of the left and right side surfaces and the engagement holes E2 are formed on the other corresponding left and right side surfaces. May be That is, when the first case 40 and the second case 50 are fitted, the engagement claw E1 engages with the engagement hole E2. The battery assembly 1 is not limited to the configuration by the engagement of the claws and the holes. For example, the first case 40 and the second case 50 may be fitted together by holding an arbitrary convex portion protruding from the left and right side surfaces of each of the first case 40 and the second case 50 by an elastic member such as a clip. Further, the first case 40 and the second case 50 may be fitted by any fastening structure such as screwing. As described above, the battery assembly 1 may have any engagement structure as long as the first case 40 and the second case 50 can be reliably fitted. As a result, the assembled battery 1 can realize good assembly, and as a result, can contribute to improvement in product reliability.

  Although the configuration in which the contact portion 44 is provided only in the first case 40 has been described above, the present invention is not limited to this. For example, the second case 50 may have an abutting portion, and in this case, the abutting portion may be configured by at least one of the first inner wall 54a, the second inner wall 54b, and the third inner wall 54c. . Also, both the first case 40 and the second case 50 may have a contact portion.

  The assembled battery 1 may not have the tapered portions 45 a and 55 a as long as the insertability of the battery cell 10 into the first case 40 and the second case 50 can be ensured.

  The battery assembly 1 is not limited to the configuration in which the guide portions 45 and 55 are provided independently. For example, the battery assembly 1 may be configured such that the first insulating portions 46 a and 56 a are used as a guide portion without providing the guide portions 45 and 55. In this case, the insertability of the battery cell 10 may be improved by providing the first insulating portions 46 a and 56 a with a tapered shape.

  In the battery assembly 1, the restraint plate 30 may be disposed on the lower surface side of the battery cell assembly 100 together with the opening O. As a result, the battery cell assembly 100 is held between the upper and lower directions by the highly rigid restraint plate 30, so that the pressure retention is further improved.

  Similarly, in the battery assembly 1, the insulating sheet 20 may be disposed on the lower surface side of the battery cell assembly 100. Thereby, the assembled battery 1 can further improve the insulation.

  The number of battery cells 10 and the number of windows 42 and 52 are not limited to the above configuration. The number of battery cells 10 may be any number. The windows 42 and 52 may be formed in an optimal manner according to the number of battery cells 10.

DESCRIPTION OF SYMBOLS 1 assembled battery 10, 10a, 10b, 10c, 10e, 10f battery cell 11 outer surface 12p, 12n electrode tab 13 outer surface 14 exterior member 20 insulating sheet 30 insulating plate 31 restraint plate 31 hole 32 recess 40 first case 40a bottom 41 screw hole 42, 42a, 42b, 42c, 42d Window portion 421, 421a, 421b, 421c, 421d Window portion 422, 422a, 422b, 422c Window portion 43 Jig insertion hole 44 Contact portion 44a First inner wall (inner wall)
44b second inner wall 44c third inner wall 45 guide portion 45a tapered portion 46a first insulating portion (insulating portion)
46b second insulating portion 47, 47a, 47b, 47c, 47d accommodation portion 471, 471a, 471b, 471c, 471d accommodation portion 472, 472a, 472b, 472c accommodation portion 50 second case 51 screw hole 52, 52a, 52b, 52c Window 53 jig insertion hole 54a first inner wall (inner wall)
54b second inner wall 54c third inner wall 55 guide portion 55a tapered portion 56a first insulating portion (insulating portion)
56b second insulating portion 57, 57a, 57b, 57c accommodation portion 60a total plus bus bar 60b total minus bus bar 70a, 70b jig 80 housing 80a bottom surface 81 support portion 81a screw hole 90 discharge portion 91 discharge tube 100 battery cell assembly E1 engagement Joint claw E2 engagement hole F fixing part O opening S1 connection surface S2 tip surface

Claims (8)

A battery cell assembly comprising a plurality of battery cells stacked;
A first case and a second case that internally support the battery cell assembly in a mutually engaged state;
A constraining plate covering the battery cell assembly from one of the stacking directions;
Equipped with
The one end face of the battery cell assembly is pressurized by the restraint plate, and the other end face abuts on the bottom surfaces of the engaged first case and the second case.
Battery pack. The upper surface of the engaged first case and the second case opposite to the bottom surface is constituted by an opening.
The assembled battery according to claim 1. The restraint plate has a recess recessed toward the one end face of the battery cell assembly.
The assembled battery according to claim 1. An insulating sheet is disposed between the restraint plate and the one end face,
An assembled battery according to any one of claims 1 to 3. The bottom surfaces of the first case and the second case are in contact with the bottom surface of a housing for housing the battery assembly therein.
An assembled battery according to any one of claims 1 to 4. Fixing portions of the first case and the second case with respect to the case are provided inside the bottom surface of the case.
The assembled battery according to claim 5. The first case and the second case are made of a metal material or a resin material having an electrically insulating material applied to the surface.
The assembled battery according to any one of claims 1 to 6. The restraint plate is made of a metal material or a resin material having an electrically insulating material applied to the surface thereof.
The assembled battery according to any one of claims 1 to 7.