JP7224903B2 - BATTERY, BATTERY ASSEMBLY AND BATTERY MODULE - Google Patents

Description

Embodiments of the present invention relate to batteries, battery assemblies, and battery modules.

Generally, a battery such as a secondary battery includes an electrode group including a positive electrode and a negative electrode, and an exterior portion that houses the electrode group. In some batteries, an exterior portion is formed from two exterior members, and each of the two exterior members is formed from a metal such as stainless steel. In this battery, the first exterior member, which is one of the exterior members, is formed in a bottomed box-tube shape having a bottom wall and side walls, and the bottom wall and side walls define an internal space for accommodating the electrode group. . In the first exterior member, an opening of the internal space is formed on the side opposite to the bottom wall. Further, the first exterior member is formed with a flange that protrudes outward from the edge of the opening of the internal space. In this battery, the second exterior member is arranged to face the flange and closes the opening of the internal space. The flange and the second exterior member protrude outward from the opening edge with respect to the side wall. The flange and the second exterior member protrude outward from the edge of the opening to form a welded portion over the entire circumference of the opening where the flange and the second exterior member are airtightly welded. The internal space is sealed from the outside by welding the flange and the second armor member. Also, in the battery, a pair of electrode terminals (a positive electrode terminal and a negative electrode terminal) is attached to the outer surface of the side wall of the first exterior member.

A battery assembly is formed by housing the above-described batteries in the housing space of the case. A battery module is formed by stacking a plurality of such battery assemblies in the stacking direction. In such a battery module, the batteries of the battery assembly stacked adjacent to each other are electrically connected to each other by connecting members such as bus bars. In the battery module as described above, it is required that the positional relationship between the battery and the case in the direction perpendicular or substantially perpendicular (intersecting) to the stacking direction does not vary from battery assembly to battery assembly. In other words, it is required that the batteries in the storage spaces of all the battery assemblies be accurately arranged with respect to the case without variation among the battery assemblies.

JP 2017-216087 A JP 2017-216088 A

SUMMARY OF THE INVENTION An object of the present invention is to provide a battery assembly housed in a case, in which batteries are accurately arranged with respect to the case in the housing space. Another object of the present invention is to provide a battery assembly including the battery and a battery module including a plurality of the battery assemblies.

According to an embodiment, a battery includes a first exterior member, an electrode group, a second exterior member, a weld, a first terminal, a second terminal, and a spring. The first exterior member has a bottom wall and side walls that define an internal space, and is made of metal. The first exterior member has an opening for the internal space formed on the side opposite to the bottom wall, and the first exterior member includes a flange projecting outward from the edge of the opening to the side wall. The electrode group includes a positive electrode and a negative electrode, and is accommodated in the internal space of the first exterior member. The second exterior member is made of metal and arranged to face the flange while closing the opening of the internal space. The welded portion is formed in a portion protruding outward from the opening edge of the flange and the second exterior member, and the flange and the second exterior member are welded at the welded portion. The first terminal and the second terminal are attached as a pair of electrode terminals to the outer surface of the side wall of the first exterior member, and are arranged on the same side or opposite sides of each other in the lateral direction. , projecting at the outer surface of the side wall. The spring portion is formed from at least one of the flange and the second exterior member at a portion protruding from the opening edge of the flange and the second exterior member, and the side where the first terminal protrudes in the lateral direction, or , protrudes from the side wall opposite to the side from which the first terminal protrudes. When the spring portion is elastically deformed by the action of an external force from the outside, a repulsive force having a force component in the lateral direction opposite to the side where the spring portion protrudes from the side wall is generated as a reaction to the elastic force. It acts on one armor member and the second armor member.

Embodiments also provide a battery assembly comprising the aforementioned battery and a case. The case includes a case bottom wall and case side walls that define a storage space, and the case has a case opening as an opening of the storage space on the opposite side of the case bottom wall. A battery is housed in the housing space. In the storage space, as a reaction to the elastic force of the spring portion, a repulsive force from the side wall of the case acts on the battery. In the storage space, the battery abuts against the side wall of the case at the reference end, which is the end opposite to the side where the spring portion protrudes in the lateral direction, due to the repulsive force from the side wall of the case.

Moreover, according to the embodiment, a battery module including a plurality of the battery assemblies described above is provided.

FIG. 1 is a perspective view schematically showing the battery according to the first embodiment. FIG. FIG. 2 is a perspective view showing the battery according to the first embodiment disassembled for each member. FIG. 3 is a schematic diagram illustrating the configuration of the electrode group according to the first embodiment. FIG. 4 is a sectional view schematically showing section A1 in FIG. FIG. 5 is a cross-sectional view schematically showing an enlarged region H1 in FIG. FIG. 6 is a cross-sectional view schematically showing an enlarged region H2 in FIG. FIG. 7 is a perspective view schematically showing a state immediately after the flange and the second exterior member are welded at the welded portion in the manufacture of the battery according to the first embodiment. 8 is a perspective view schematically showing a state in which a part of the surplus portion of the second exterior member is trimmed from the state of FIG. 7. FIG. FIG. 9 is a cross-sectional view schematically showing the configuration of a spring portion and its vicinity in a battery according to a first modification of the first embodiment. FIG. 10 is a cross-sectional view schematically showing the configuration of a spring portion and its vicinity in a battery according to a second modification of the first embodiment. FIG. 11 is a cross-sectional view schematically showing the structure of a spring portion and its vicinity in a battery according to a third modification of the first embodiment. FIG. 12 is a cross-sectional view schematically showing the configuration of the end portion of the battery according to the fourth modification of the first embodiment, which is opposite to the side where the spring portion protrudes. 13 is a perspective view schematically showing a battery according to a fifth modification of the first embodiment; FIG. FIG. 14 is a perspective view schematically showing a battery assembly according to the second embodiment. FIG. 15 is a perspective view schematically showing the case of the battery assembly according to the second embodiment. FIG. 16 is a perspective view schematically showing the case of the battery assembly according to the second embodiment when viewed from a direction different from that of FIG. 15. FIG. 17 is a cross-sectional view schematically showing a cross-section A2 of FIG. 14. FIG. 18 is a cross-sectional view schematically showing an enlarged region H3 of FIG. 17. FIG. FIG. 19 is a cross-sectional view schematically showing an enlarged region H4 in FIG. 20 is a perspective view schematically showing a case of a battery assembly according to a first modification of the second embodiment; FIG. FIG. 21 is a schematic diagram showing a case of a battery assembly according to a second modification of the second embodiment, viewed from the side where the case opening opens. FIG. 22 is a perspective view schematically showing a battery module according to the third embodiment; FIG. FIG. 23 is a perspective view schematically showing a battery module according to a third embodiment with some parts disassembled. FIG. 24 is a cross-sectional view schematically showing a stacking state of battery assemblies stacked adjacent to each other in the battery module according to the third embodiment. FIG. 25 is a perspective view schematically showing the configuration of the busbars of the battery module according to the third embodiment. FIG. 26 is a cross-sectional view schematically showing a state of electrical connection by bus bars of battery assemblies stacked adjacent to each other in the battery module according to the third embodiment. FIG. 27 is a cross-sectional view schematically showing a stacking state of battery assemblies stacked adjacent to each other in the battery module according to the first modification of the third embodiment. 28 is a perspective view schematically showing a lid of a battery module according to a second modification of the third embodiment; FIG. 29 is a cross-sectional view schematically showing an electrical connection state of battery assemblies stacked adjacent to each other by bus bars in a battery module according to a third modification of the third embodiment; FIG. .

Hereinafter, embodiments will be described with reference to the drawings.

[battery]
First, a battery according to an embodiment will be described.

(First embodiment)
FIG. 1 shows a battery 1 according to a first embodiment as an example of a battery. FIG. 2 shows the battery 1 disassembled for each member. The battery 1 is a secondary battery, such as a non-aqueous electrolyte battery. As shown in FIGS. 1 and 2 , the battery 1 has an exterior portion 3 . The exterior part 3 is formed from a first exterior member 5 and a second exterior member 6 . Each of the exterior members 5 and 6 is made of metal such as stainless steel. Examples of metals other than stainless steel that form the exterior members 5 and 6 include aluminum, aluminum alloys, carbon steel, plated steel, and the like. The first exterior member 5 is formed in the shape of a box with a bottom. In this embodiment, the first exterior member 5 has a bottom wall 7 and two pairs of side walls 8A, 8B, 9A, 9B, and is formed in a substantially rectangular box shape with a bottom. In the first exterior member 5, the bottom wall 7 and side walls 8A, 8B, 9A, and 9B define an internal space 11 (see FIGS. 4 to 6 described later). The electrode group 10 is housed in the internal space 11 . In addition, in the exterior part 3 including the first exterior member 5 and the second exterior member 6, the side where the internal space 11 is located is the inside, and the side opposite to the side where the internal space 11 is located is the outside.

The internal space 11 has an opening 12 (see FIGS. 4 to 6 described later) on the opposite side of the bottom wall 7 . Here, in the battery 1, the vertical direction (direction indicated by arrows X1 and X2), the horizontal direction (direction indicated by arrows Y1 and Y2) perpendicular or substantially perpendicular (crossing) to the longitudinal direction, and the vertical direction Define a thickness direction (direction indicated by arrow Z1 and arrow Z2) that is perpendicular or substantially perpendicular (intersecting) to both the direction and the lateral direction. In the battery 1, each of the pair of side walls 8A and 8B extends in the vertical direction and is continuous from the side wall 9A to the side wall 9B in the vertical direction. Each of the pair of side walls 9A and 9B extends in the lateral direction and continues in the lateral direction from the side wall 8A to the side wall 8B. A side wall (first side wall) 8A and a side wall (second side wall) 8B face each other across the internal space 11 and are arranged apart in the lateral direction. The side wall (third side wall) 9A and the side wall (fourth side wall) 9B face each other across the internal space 11 and are spaced apart in the vertical direction. Each of the side walls 8A, 8B, 9A, and 9B extends from the bottom wall 7 toward the opening 12, and the internal space 11 opens toward one side (arrow Z2 side) in the thickness direction of the opening 12. do. The opening plane of the opening 12 is parallel or substantially parallel to the vertical and horizontal directions.

As shown in FIGS. 1 and 2 , the first exterior member 5 is provided with a flange 13 on the opposite side of the bottom wall 7 . The flange 13 protrudes outward (peripheral side) from an opening edge 15 (see FIGS. 4 to 6 described later) of the opening 12 along the entire circumference of the opening 12 . Therefore, the flange 13 protrudes from the side walls 8A, 8B, 9A, 9B in the direction parallel to the opening surface of the opening 12, away from the opening 12. As shown in FIG. In the present embodiment, the area surrounded by the side walls 8A, 8B, 9A, and 9B in the cross section perpendicular or substantially perpendicular to the thickness direction of the battery 1 has a rectangular shape or a substantially rectangular shape, but is not limited to this. do not have. In some embodiments, the area surrounded by the side walls in a cross section perpendicular or substantially perpendicular to the thickness direction of the battery 1 may be formed in a polygonal shape other than a rectangular shape, an elliptical shape, or the like.

The second exterior member 6 is formed in a substantially plate shape. The second exterior member 6 is arranged to face the flange 13 and attached to the flange 13 from the side where the opening 12 opens. In this embodiment, the second exterior member 6 protrudes outward (away from the center of the opening 12 ) from the opening edge 15 over the entire circumference of the opening 12 in the circumferential direction. Therefore, the second exterior member 6 protrudes from the side walls 8A, 8B, 9A, 9B in the direction parallel to the opening surface of the opening 12, away from the opening 12. As shown in FIG. In a region outside the opening edge 15 , the second exterior member 6 faces the flange 13 over the entire circumference of the opening 12 . Also, the second exterior member 6 closes the opening 12 of the internal space 11 . In the portion where the second exterior member 6 closes the opening 12 , the thickness direction of the substantially plate-like second exterior member 6 coincides or substantially coincides with the thickness direction of the battery 1 .

Note that the distance from the bottom wall 7 to the opening 12 is much smaller than the distance between the side walls 8A and 8B and the distance between the side walls 9A and 9B. In the battery 1, the dimension in the thickness direction is much smaller than the dimension in the vertical direction and the dimension in the horizontal direction. In addition, in the present embodiment, the distance between the side walls 8A and 8B is larger than the distance between the side walls 9A and 9B, and the battery 1 has a lateral dimension greater than a vertical dimension of big. Here, the distance between the side walls 8A and 8B corresponds to the dimension of the internal space 11 (opening 12) in the lateral direction of the battery 1. The distance between the side walls 9A and 9B corresponds to the dimension of the internal space 11 (opening 12) of the battery 1 in the vertical direction. The distance from the bottom wall 7 to the opening 12 corresponds to the dimension of the internal space 11 in the thickness direction of the battery 1 .

In one embodiment, the distance between sidewalls 8A, 8B is smaller than the distance between sidewalls 9A, 9B, and the cell 1 has a lateral dimension smaller than a vertical dimension. good too. In another embodiment, the distance between side walls 8A and 8B is the same or substantially the same as the distance between side walls 9A and 9B, and in battery 1 the dimensions in the lateral direction are the same as in the vertical direction. The dimensions may be the same or substantially the same. However, in either case, the distance from bottom wall 7 to opening 12 is much smaller than the distance between side walls 8A and 8B and the distance between side walls 9A and 9B, respectively.

In one embodiment, each of the bottom wall 7, the side walls 8A, 8B, 9A, 9B and the flange 13 of the first exterior member 5 has a thickness of 0.02 mm or more and 3 mm or less. The substantially plate-shaped second exterior member 6 has a thickness of 0.02 mm or more and 3 mm or less. Further, in the present embodiment, the outward projection dimension of the flange 13 from the opening edge 15 (side walls 8A, 8B, 9A, 9B) is about 2 mm or more and 5 mm or less. That is, the distance from the opening edge 15 of the opening 12 to the outer edge E1 of the flange 13 is about 2 mm or more and 5 mm or less. In addition, in the range where spring portions 35A and 35B and bent portions 41A and 41B described later are not formed in the circumferential direction of the opening 12, from the opening edge 15 (side walls 8A, 8B, 9A and 9B) of the second exterior member 6 The outward projection dimension is about 2 mm or more and 5 mm or less. That is, in the range where spring portions 35A and 35B and bent portions 41A and 41B, which will be described later in the circumferential direction of the opening 12, are not formed, the distance from the opening edge 15 of the opening 12 to the outer edge E2 of the second exterior member 6 is It is about 2 mm or more and 5 mm or less.

FIG. 3 is a diagram illustrating the configuration of the electrode group 10. As shown in FIG. As shown in FIG. 3 , the electrode group 10 is formed in a flat shape, for example, and includes a positive electrode 21 , a negative electrode 22 , and separators 23 and 25 . The positive electrode 21 includes a positive electrode current collector foil 21A as a positive electrode current collector, and a positive electrode active material-containing layer 21B carried on the surface of the positive electrode current collector foil 21A. The positive current collector foil 21A is an aluminum foil, an aluminum alloy foil, or the like, and has a thickness of about 10 μm to 20 μm. A slurry containing a positive electrode active material, a binder, and a conductive agent is applied to the positive current collector foil 21A. Examples of the positive electrode active material include, but are not limited to, oxides, sulfides, and polymers that can intercalate and deintercalate lithium. Moreover, from the viewpoint of obtaining a high positive electrode potential, it is preferable that the positive electrode active material is lithium-manganese composite oxide, lithium-nickel composite oxide, lithium-cobalt composite oxide, lithium iron phosphate, or the like.

The negative electrode 22 includes a negative electrode current collector foil 22A as a negative electrode current collector, and a negative electrode active material containing layer 22B carried on the surface of the negative electrode current collector foil 22A. The negative electrode collector foil 22A is an aluminum foil, an aluminum alloy foil, a copper foil, or the like, and has a thickness of about 10 μm to 20 μm. A slurry containing a negative electrode active material, a binder, and a conductive agent is applied to the negative electrode current collector foil 22A. Examples of the negative electrode active material include, but are not limited to, metal oxides, metal sulfides, metal nitrides, and carbon materials that can occlude and release lithium ions. As the negative electrode active material, a material having a lithium ion absorption/discharge potential of 0.4 V or more relative to the metal lithium potential, that is, a lithium ion absorption/discharge potential of 0.4 V (vs. Li ⁺ /Li) or more. It is preferably a substance. By using a negative electrode active material having such a lithium ion absorption/release potential, the alloy reaction between aluminum or an aluminum alloy and lithium is suppressed. Allows the use of aluminum alloys. Examples of the negative electrode active material having a lithium ion absorption/discharge potential of 0.4 V (vs. Li ⁺ /Li) or higher include titanium oxides, lithium-titanium composite oxides such as lithium titanate, tungsten oxides, and amorphous tin. oxides, niobium-titanium composite oxides, tin silicon oxides, silicon oxides, and the like, and it is particularly preferable to use lithium-titanium composite oxides as the negative electrode active material. Note that when a carbon material that absorbs and releases lithium ions is used as the negative electrode active material, a copper foil may be used as the negative electrode current collector foil 22A. The carbon material used as the negative electrode active material has a lithium ion absorption/desorption potential of about 0 V (vs. Li ⁺ /Li).

The aluminum alloy used for the positive electrode current collector foil 21A and the negative electrode current collector foil 22A desirably contains one or more elements selected from Mg, Ti, Zn, Mn, Fe, Cu and Si. The purity of aluminum and aluminum alloys can be 98 wt% or higher, preferably 99.99 wt% or higher. Also, pure aluminum with a purity of 100% can be used as a material for the positive electrode current collector and/or the negative electrode current collector. The content of transition metals such as nickel and chromium in aluminum and aluminum alloys is preferably 100 ppm by weight or less (including 0 ppm by weight).

In the positive current collector foil 21A, a positive current collector tab 21D is formed by one long side edge 21C and its vicinity. In this embodiment, the positive electrode current collecting tab 21D is formed over the entire length of the long edge 21C. In the positive electrode current collector tab 21D, the positive electrode active material containing layer 21B is not carried on the surface of the positive electrode current collector foil 21A. Further, in the negative electrode current collector foil 22A, a negative electrode current collector tab 22D is formed by one long side edge 22C and its vicinity. In this embodiment, the negative electrode current collecting tab 22D is formed over the entire length of the long edge 22C. In the negative electrode current collecting tab 22D, the negative electrode active material containing layer 22B is not carried on the surface of the negative electrode current collecting foil 22A.

Each of the separators 23 and 25 is made of an electrically insulating material, and electrically insulates between the positive electrode 21 and the negative electrode 22 . Each of the separators 23 and 25 may be a sheet or the like separate from the positive electrode 21 and the negative electrode 22 , or may be formed integrally with one of the positive electrode 21 and the negative electrode 22 . Also, the separators 23 and 25 may be made of an organic material, an inorganic material, or a mixture of an organic material and an inorganic material. Examples of organic materials forming the separators 23 and 25 include engineering plastics and super engineering plastics. Engineering plastics include polyamide, polyacetal, polybutylene terephthalate, polyethylene terephthalate, syndiotactic polystyrene, polycarbonate, polyamideimide, polyvinyl alcohol, polyvinylidene fluoride, and modified polyphenylene ether. Super engineering plastics include polyphenylene sulfide, polyetheretherketone, liquid crystal polymer, polyvinylidene fluoride, polytetrafluoroethylene (PTFE), polyethernitrile, polysulfone, polyacrylate, polyetherimide and thermoplastic polyimide. be done. Inorganic materials forming the separators 23 and 25 include oxides (eg, aluminum oxide, silicon dioxide, magnesium oxide, phosphorous oxide, calcium oxide, iron oxide, titanium oxide), nitrides (eg, boron nitride, aluminum nitride, silicon nitride, barium nitride) and the like.

In the electrode group 10, the positive electrode 21, the negative electrode 22, and the separators 23, 25 are arranged around the winding axis B while the separators 23, 25 are sandwiched between the positive electrode active material-containing layer 21B and the negative electrode active material-containing layer 22B. is wound around in a flat shape. At this time, for example, the positive electrode 21, the separator 23, the negative electrode 22, and the separator 25 are wound while being stacked in this order. Further, in the electrode group 10, the positive electrode current collecting tab 21D of the positive electrode current collecting foil 21A protrudes to one side in the direction along the winding axis B with respect to the negative electrode 22 and the separators 23 and 25. As shown in FIG. Then, the negative electrode current collecting tab 22D of the negative electrode current collecting foil 22A protrudes from the positive electrode 21 and the separators 23, 25 in the direction along the winding axis B opposite to the side where the positive electrode current collecting tab 21D projects. do. The electrode group 10 is arranged such that the winding axis B is parallel or substantially parallel to the lateral direction of the battery 1 . That is, the electrode group 10 is arranged in the internal space 11 in a state in which the winding axis B is perpendicular or substantially perpendicular (intersects) the thickness direction of the battery 1 .

In one embodiment, the electrode assembly 10 is impregnated with an electrolyte (not shown) in the interior space 11 . As the electrolytic solution, a non-aqueous electrolytic solution is used, and for example, a non-aqueous electrolytic solution prepared by dissolving an electrolyte in an organic solvent is used. In this case, as the electrolyte dissolved in the organic solvent, lithium perchlorate (LiClO ₄ ), lithium hexafluorophosphate (LiPF ₆ ), lithium tetrafluoroborate (LiBF ₄ ), lithium arsenic hexafluoride (LiAsF ₆ ), lithium salts such as lithium trifluoromethanesulfonate (LiCF ₃ SO ₃ ) or lithium bistrifluoromethylsulfonylimide [LiN(CF ₃ SO ₂ ) ₂ ], and mixtures thereof. In addition, as an organic solvent, cyclic carbonates such as propylene carbonate (PC), ethylene carbonate (EC) and vinylene carbonate; chain carbonates such as diethyl carbonate (DEC), dimethyl carbonate (DMC) and methyl ethyl carbonate (MEC); tetrahydrofuran cyclic ethers such as (THF), 2-methyltetrahydrofuran (2MeTHF), and dioxolane (DOX); linear ethers such as dimethoxyethane (DME) and diethoxyethane (DEE); γ-butyrolactone (GBL), acetonitrile (AN) and sulfolane (SL). These organic solvents are used alone or as a mixed solvent.

In one embodiment, a non-aqueous gel electrolyte obtained by combining a non-aqueous electrolyte and a polymer material is used instead of the non-aqueous electrolyte. In this case, the electrolyte and organic solvent described above are used. Polymer materials include polyvinylidene fluoride (PVdF), polyacrylonitrile (PAN), and polyethylene oxide (PEO).

In some embodiments, a solid electrolyte such as a polymer solid electrolyte and an inorganic solid electrolyte is provided as the nonaqueous electrolyte instead of the nonaqueous electrolyte. In this case, the electrode group 10 may not be provided with the separators 23 and 25 . In the electrode group 10 , a solid electrolyte is sandwiched between the positive electrode 21 and the negative electrode 22 instead of the separators 23 and 25 . Therefore, in this embodiment, the positive electrode 21 and the negative electrode 22 are electrically insulated by the solid electrolyte.

FIG. 4 shows cross section A1 of FIG. 5 shows an enlarged view of the region H1 of FIG. 4, and FIG. 6 shows an enlarged view of the region H2 of FIG. As shown in FIGS. 4 to 6 and the like, the battery 1 is formed with a welded portion 30 for hermetically welding the flange 13 and the second exterior member 6 . The welded portion 30 is provided on the outside of the opening edge 15 of the opening 12 , that is, on the side away from the opening 12 in the direction parallel to the opening surface of the opening 12 . Therefore, the welded portions 30 are provided in the flange 13 and the second exterior member 6 at portions protruding outward from the side walls 8A, 8B, 9A, 9B (opening edges 15). The welded portion 30 extends along the opening edge 15 and is formed continuously over the entire circumference of the opening 12 in the circumferential direction. Therefore, the flange 13 and the second exterior member 6 are hermetically welded over the entire circumference of the opening 12 in the circumferential direction. Since the flange 13 and the second exterior member 6 are hermetically welded at the welded portion 30 as described above, the internal space 11 is hermetically sealed.

At the welded portion 30, the flange 13 and the second exterior member 6 are welded by, for example, resistance seam welding. By performing resistance seam welding, the cost can be reduced and the airtightness between the flange 13 and the second exterior member 6 is high compared to laser welding or the like.

As shown in FIGS. 1 and 2, terminals 27A and 27B are attached to the outer surface of the first exterior member 5 as a pair of electrode terminals. One of the terminals 27A and 27B becomes a positive terminal of the battery 1, and the other of the terminals 27A and 27B becomes a negative terminal of the battery 1. Thus, terminals 27A and 27B have opposite electrical polarities with respect to each other. In this embodiment, the terminal (first terminal) 27A is attached to the side wall (first side wall) 8A while being exposed to the outside, and the terminal (second terminal) 27B is attached to the side wall while being exposed to the outside. (Second side wall) Attached to 8B. Therefore, the terminal 27A protrudes laterally to one side from the outer surface of the side wall 8A, and the terminal 27B laterally protrudes from the outer surface of the side wall 8B to the side opposite to the side from which the terminal 27A protrudes. In an example such as FIG. 1, the terminal 27A is arranged at the center position or approximately the center position of the side wall 8A in the longitudinal direction of the battery 1, and the terminal 27B is arranged at the center position or approximately the center position of the side wall 8B in the longitudinal direction of the battery 1. placed. Each of the terminals 27A and 27B is made of a conductive material, such as aluminum or copper.

Also, the terminals 27A and 27B are connected to a bus bar 36 (see FIGS. 22 and 23 described later), which is a connection member for electrically connecting the battery 1 and another battery. The terminal 27A has a terminal-side contact surface 37A with which the busbar 36 to be connected contacts, and the terminal 27B has a terminal-side contact surface 37B with which the busbar 36 to be connected contacts. In this embodiment, the terminal-side contact surfaces 37A and 37B face outward in the lateral direction and face opposite to each other in the lateral direction.

A pair of insulating members 28A and 28B made of an electrically insulating material are provided on the outer surface of the first exterior member 5. As shown in FIG. The insulating member 28A is arranged on the outer surface of the side wall 8A, and the insulating member 28B is arranged on the outer surface of the side wall 8B. The insulating member 28A is interposed between the outer surface of the side wall 8A and the terminal 27A, and electrically insulates the terminal 27A from the exterior portion 3 (first exterior member 5). The insulating member 28B is interposed between the outer surface of the side wall 8B and the terminal 27B, and electrically insulates the terminal 27B from the exterior portion 3 (first exterior member 5). In the battery 1, the terminal 27A is arranged on the side (inner side) closer to the central position of the side wall 8A with respect to both outer edges of the insulating member 28A in the vertical direction. The terminal 27B is arranged on the side (inner side) closer to the central position of the side wall 8B with respect to both outer edges of the insulating member 28B in the vertical direction.

Also, the battery 1 is provided with a pair of leads 31A and 31B (see FIGS. 26 and 29 described later) as a positive electrode lead and a negative electrode lead. A positive lead, which is one of the pair of leads 31A, 31B, electrically connects the positive current collecting tab 21D of the electrode group 10 to a corresponding positive terminal, which is one of the pair of terminals 27A, 27B. Further, the negative electrode current collecting tab 22D of the electrode group 10 is electrically connected to the corresponding negative electrode terminal of the pair of terminals 27A and 27B by the negative electrode lead that is the other of the pair of leads 31A and 31B. In addition, the electrode group 10 including the positive electrode current collecting tab 21D and the negative electrode current collecting tab 22D and the pair of leads 31A and 31B are connected to an insulating band 32 wound on the outermost layer of the electrode group 10 and the inner surface of the exterior part 3. Contact with the exterior part 3 is prevented by insulating members 33A and 33B (see FIGS. 24 and 26, etc., which will be described later), etc., which are arranged in the outer part 3. As shown in FIG. Therefore, the electrode group 10 and the leads 31A and 31B are electrically insulated from the exterior part 3 (the first exterior member 5 and the second exterior member 6).

As shown in FIGS. 1, 2, 4, 5, etc., spring portions 35A and 35B are formed at portions of the flange 13 and the second exterior member 6 protruding outward from the opening edge 15. As shown in FIG. The spring portion 35A is provided in a range in which the side wall (first side wall) 8A extends in the circumferential direction of the opening 12, and extends along the vertical direction. Further, the spring portion 35B is provided in a range in which the side wall (third side wall) 9A extends in the circumferential direction of the opening 12, and extends along the horizontal direction. However, the spring portion 35A is provided at a position apart from the terminal (first terminal) 27A in the circumferential direction of the opening 12 . The spring portions 35A and 35B are provided at positions apart from the terminals 27A and 27B in the circumferential direction of the opening 12 . Although the spring portion 35B is shown in FIGS. 4 and 5, the spring portion 35A has the same configuration as the spring portion 35B.

In this embodiment, the spring portions 35A and 35B are formed only from the second exterior member 6. As shown in FIG. In each of the spring portions 35A and 35B, the second exterior member 6 protrudes outward from the welded portion 30 and protrudes outward from the outer edge E1 of the flange 13 . Each of the spring portions 35A and 35B is formed by a portion projecting outward from the outer edge E1 of the flange 13 in the second exterior member 6. As shown in FIG. Therefore, within the range where the spring portion 35A is formed in the circumferential direction of the opening 12, the welded portion 30 is provided between the opening edge 15 and the spring portion 35A. In the range where the spring portion 35B is formed in the circumferential direction of the opening 12, the welded portion 30 is provided between the opening edge 15 and the spring portion 35B.

The spring portion (first spring portion) 35A protrudes laterally from the side wall 8A toward the side where the terminal (first terminal) 27A protrudes, and protrudes laterally outward from the outer edge E1 of the flange 13 . The spring portion (second spring portion) 35B protrudes to one side in the longitudinal direction with respect to the side wall 9A and protrudes outward in the longitudinal direction from the outer edge E1 of the flange. In this embodiment, since the spring portions 35A and 35B are formed only from the second exterior member 6, the thickness of the second exterior member 6 is preferably thick to some extent. The thickness of 6 is preferably thicker than the thickness of first exterior member 5 .

In the range where the spring portion 35A is formed in the circumferential direction of the opening 12, a bending line M1 and a folding line N1 are formed in the protruding portion of the second exterior member with respect to the side wall 8A. Each of the bending line M1 and the folding line N1 extends along the vertical direction of the battery 1 . The second exterior member 6 is bent at the bending line M1 and folded back at the folding line N1. Bend line M1 is located outside welded portion 30 and outside edge E1 of flange 13 . 35 A of spring parts are formed in the part between the bending line M1 and the outer edge E2 in the 2nd exterior member 6. As shown in FIG.

The second exterior member 6 extends laterally outward from the opening edge 15 to the folding line M1. By bending the second exterior member 6 along the folding line M1, the second exterior member 6 extends from the folding line M1 to the folding line N1 toward the side where the bottom wall 7 is located in the thickness direction of the battery 1. extended. By folding back the second exterior member 6 along the folding line N1, the second exterior member 6 extends from the folding line N1 to the outer edge E2 in the thickness direction of the battery 1 on the side where the bottom wall 7 is located. Extends to the opposite side. In this embodiment, the extending portion from the folding line N1 to the outer edge E2 in the second exterior member 6 is the extending portion from the folding line M1 to the folding line N1 in the second exterior member 6 and the side wall 8A. , and positioned inside the extending portion of the second exterior member 6 from the folding line M1 to the folding line N1.

In the range where the spring portion 35B is formed in the circumferential direction of the opening 12, a bending line M2 and a folding line N2 are formed in the protruding portion of the second exterior member with respect to the side wall 9A. Each of the bending line M2 and the folding line N2 extends along the horizontal direction of the battery 1 . The second exterior member 6 is bent at the bending line M2 and folded back at the folding line N2. Bending line M2 is located outside welded portion 30 and outside edge E1 of flange 13 . The spring portion 35B is formed from a portion of the second exterior member 6 between the bending line M2 and the outer edge E2.

The second exterior member 6 extends outward in the longitudinal direction from the opening edge 15 to the bending line M2. By bending the second exterior member 6 along the folding line M2, the second exterior member 6 extends from the folding line M2 to the folding line N2 toward the side where the bottom wall 7 is located in the thickness direction of the battery 1. extended. By folding back the second exterior member 6 along the folding line N2, the second exterior member 6 extends from the folding line N2 to the outer edge E2 in the thickness direction of the battery 1 on the side where the bottom wall 7 is located. Extends to the opposite side. In this embodiment, the extending portion from the folding line N2 to the outer edge E2 in the second exterior member 6 is the extension portion from the folding line M2 to the folding line N2 in the second exterior member 6 and the side wall 9A. , and positioned inside the extended portion of the second exterior member 6 from the folding line M2 to the folding line N2.

When force acts on the spring portion (first spring portion) 35A from the outside, the spring portion 35A is elastically deformed. Due to the elastic deformation of the spring portion 35A, a repulsive force having a force component in the lateral direction opposite to the side where the spring portion 35A protrudes from the side wall 8A acts as a reaction to the elastic force and acts on the exterior portion 3 (second It acts on a battery 1 comprising one casing member 5 and a second casing member 6). Further, the spring portion (second spring portion) 35B is elastically deformed by external force acting on the spring portion (second spring portion) 35B. Due to the elastic deformation of the spring portion 35B, a repulsive force having a force component directed to the side opposite to the side where the spring portion 35B protrudes from the side wall 9A in the vertical direction acts as a reaction to the elastic force, and acts on the exterior portion 3 (second It acts on a battery 1 comprising one casing member 5 and a second casing member 6).

As shown in FIGS. 1, 2, 4 and 6, bending portions 41A and 41B are formed at portions of the flange 13 and the second exterior member 6 protruding from the opening edge 15 to the outside. The bent portion 41A is provided in a range in which the side wall (second side wall) 8B extends in the circumferential direction of the opening 12, and extends along the vertical direction. In addition, the bent portion 41B is provided in a range in which the side wall (fourth side wall) 9B extends in the circumferential direction of the opening 12, and extends along the horizontal direction. In addition, the bent portion 41A is provided at a position apart from the terminal (second terminal) 27B in the circumferential direction of the opening 12 . The bent portions 41A and 41B are provided at positions apart from both the terminals 27A and 27B in the circumferential direction of the opening 12 . Although the bent portion 41B is shown in FIGS. 4 and 6, the bent portion 41A has the same configuration as the bent portion 41B.

In this embodiment, the bent portions 41A and 41B are formed only from the second exterior member 6. As shown in FIG. At each of the bent portions 41A and 41B, the second exterior member 6 protrudes outward from the welded portion 30 and protrudes outward from the outer edge E1 of the flange 13 . Each of the bent portions 41A and 41B is formed by a portion of the second exterior member 6 protruding outward from the outer edge E1 of the flange 13 . Therefore, in the range where the bent portion 41A is formed in the circumferential direction of the opening 12, the welded portion 30 is provided between the opening edge 15 and the bent portion 41A. In the range where the bent portion 41B is formed in the circumferential direction of the opening 12, the welded portion 30 is provided between the opening edge 15 and the bent portion 41B.

The bent portion (first bent portion) 41A protrudes from the side wall 8B in the lateral direction opposite to the side where the spring portion (first spring portion) 35A protrudes, and laterally extends from the outer edge E1 of the flange 13. protrude outward about The bent portion (second bent portion) 41B protrudes from the side wall 9B in the longitudinal direction opposite to the side to which the spring portion (second spring portion) 35B protrudes, and extends from the outer edge E1 of the flange 13 in the longitudinal direction. protrude outward about

In the range where the bent portion 41A is formed in the circumferential direction of the opening 12, a bent line M3 is formed in the projecting portion of the second exterior member 6 with respect to the side wall 8B. The bending line M3 extends along the vertical direction of the battery 1 . The second exterior member 6 is bent at the bending line M3. Bend line M3 is located outside welded portion 30 and outside edge E1 of flange 13 . 41 A of bending parts are formed in the part between the bending line M3 and the outer edge E2 in the 2nd exterior member 6. As shown in FIG.

The second exterior member 6 extends laterally outward from the opening edge 15 to the bending line M3. By bending the second exterior member 6 along the folding line M3, the second exterior member 6 extends from the folding line M3 to the outer edge E2 toward the bottom wall 7 in the thickness direction of the battery 1. deferred. The bent portion 41A has an end surface 42A. In the battery 1, an end (reference end) P1 on the side opposite to the side where the spring portion 35A protrudes in the horizontal direction is formed by the end face 42A. The end face 42A is formed from the bending line M3 to the outer edge E2 of the second exterior member 6. As shown in FIG. In addition, the end surface 42A faces in the lateral direction opposite to the side where the spring portion 35A protrudes, and faces outward in the lateral direction.

In the range where the bent portion 41B is formed in the circumferential direction of the opening 12, a bent line M4 is formed in the projecting portion of the second exterior member 6 with respect to the side wall 9B. The bending line M4 extends along the lateral direction of the battery 1 . The second exterior member 6 is bent at the bending line M4. Bend line M4 is located outside welded portion 30 and outside edge E1 of flange 13 . The bent portion 41B is formed from a portion of the second exterior member 6 between the bending line M4 and the outer edge E2.

The second exterior member 6 extends outward in the longitudinal direction from the opening edge 15 to the bending line M4. By bending the second exterior member 6 at the bending line M4, the second exterior member 6 extends from the bending line M4 to the outer edge E2 toward the bottom wall 7 in the thickness direction of the battery 1. deferred. The bent portion 41B has an end surface 42B. In the battery 1, the end P2 opposite to the side where the spring portion 35B protrudes in the vertical direction is formed by the end surface 42B. The end face 42B is formed from the bending line M4 to the outer edge E2 of the second exterior member 6. As shown in FIG. In addition, the end surface 42B faces the side opposite to the side where the spring portion 35B protrudes in the vertical direction, and faces outward in the vertical direction.

It is preferable that each of the bent portions 41A and 41B has a shape that does not deform under external force. For example, in FIG. 6, the dimension from the bending line (M3; M4) at each of the bending portions 41A and 41B to the outer edge E2 of the second exterior member 6 is the bending distance at each of the spring portions 35A and 35B. It is smaller than the dimension from the bending line (M1; M2) to the folding line (N1; N2). That is, the dimensions of the bent portions 41A and 41B in the thickness direction of the battery 1 are smaller than the dimensions of the spring portions 35A and 35B in the thickness direction of the battery 1, respectively. As a result, even when a load similar to that applied to the spring portions 35A and 35B acts on the outer edge E2 of the second exterior member 6, the bent portions 41A and 41B have a smaller bending moment due to the applied load.

In the battery 1 of the present embodiment, the distance from the end (reference end) P1 on the side opposite to the side where the spring portion 35A protrudes to each of the terminals 27A and 27B in the lateral direction hardly varies from battery to battery 1. ,It is formed. Therefore, in each of the manufactured batteries 1, in the lateral direction, from the end P1 (end surface 42A) on the side opposite to the side where the spring portion 35A protrudes, to the terminal side contact surface 37A of the terminal (first terminal) 27A. is the same as or substantially the same as the predetermined first distance L1. In each of the manufactured batteries 1, the distance from the end P1 (end surface 42A) to the terminal-side contact surface 37B of the terminal (second terminal) 27B in the lateral direction is equal to or substantially equal to the predetermined second distance L2. be the same.

In the present embodiment, as described above, the spring portions 35A, 35B and the bent portions 41A, 41B are formed at positions apart from the terminals 27A, 27B in the circumferential direction of the opening 12, respectively. Therefore, contact of the spring portions 35A, 35B and the bent portions 41A, 41B with the terminals 27A, 27B is prevented. This ensures electrical insulation of the terminals 27A and 27B with respect to the exterior portion 3 (the first exterior member 5 and the second exterior member 6).

Moreover, the spring portions 35A and 35B and the bent portions 41A and 41B are formed as follows. FIG. 7 shows the state immediately after the flange 13 and the second exterior member 6 are welded together at the welded portion 30 in manufacturing the battery 1 . As shown in FIG. 7, immediately after the welded portion 30 is formed, the second exterior member 6 is in the shape of a rectangular plate, and the bending lines M1 to M4 and the folding lines N1 and N2 are the same as those of the second exterior member. 6 is not formed. In addition, immediately after forming the welded portion 30 , the second exterior member 6 has a surplus portion 45 protruding outward from the outer edge E<b>1 of the flange 13 . At this time, the surplus portion 45 protrudes away from the opening 12 in the direction parallel to the opening surface of the opening 12 and is formed along the entire circumference of the opening 12 in the circumferential direction. Moreover, in the range in which the side walls 8B and 9B extend in the circumferential direction of the opening 12, the surplus portion 45 from the outer edge E1 of the flange 13 is larger than the range in which the side walls 8A and 9A extend in the circumferential direction of the opening 12. The protruding length of is short.

FIG. 8 shows a state in which a part of the surplus portion 45 of the second exterior member 6 is trimmed from the state of FIG. As shown in FIG. 8, in forming the spring portions 35A and 35B and the bent portions 41A and 41B, the surplus portion 45 is partially trimmed by laser processing or the like from the state shown in FIG. 7 to form the trimming portion 46. . At this time, in the circumferential direction of the opening, the trimmed portions 46 are formed in the four rectangular corners of the second exterior member 6 and their vicinities, and in the range where the terminals 27A and 27B extend. At the trimmed portion 46 , the second covering member 6 does not protrude outward with respect to the outer edge E<b>1 of the flange 13 .

After the trimming portion 46 is formed, the above-described bending lines M1 and folding lines N1 are formed in the surplus portion 45 in the range where the side wall 8A extends in the circumferential direction of the opening, thereby forming the spring portion 35A. Further, in the range where the side wall 9A extends in the circumferential direction of the opening, the above-described folding lines M2 and folding lines N2 are formed in the surplus portion 45 to form the spring portion 35B. Then, in the range where the side wall 8B extends in the circumferential direction of the opening, the above-described bending line M3 is formed in the surplus portion 45 to form the bending portion 41A. Further, in the range where the side wall 9B extends in the circumferential direction of the opening, the above-described bending line M4 is formed in the excess portion 45 to form the bending portion 41B.

As described above, in this embodiment, the spring portions 35A and 35B and the bent portions 41A and 41B are formed from the surplus portion 45 of the second exterior member 6, respectively. Therefore, the spring portions 35A and 35B and the bent portions 41A and 41B are easily formed, and labor and the like in manufacturing the battery 1 are reduced.

(Modification of the first embodiment)
Note that the spring portions 35A and 35B are not limited to the configurations described above. In the first modification of the first embodiment shown in FIG. 9, in the spring portion 35A, the extending portion from the folding line N1 to the outer edge E2 of the second exterior member 6 extends from the folding line M1 to the folding line N1. It is located outside with respect to the extension part. That is, the extending portion of the spring portion 35A from the folding line M1 to the folding line N1 is between the extending portion of the spring portion 35A from the folding line N1 to the outer edge E2 of the second exterior member 6 and the side wall 8A. To position. In the spring portion 35B, the extending portion from the folding line N2 to the outer edge E2 of the second exterior member 6 is located outside the extending portion from the folding line M2 to the folding line N2. That is, the extending portion of the spring portion 35B from the folding screw M2 to the folding line N2 is between the extending portion of the spring portion 35B from the folding line N2 to the outer edge E2 of the second exterior member 6 and the side wall 9A. To position.

Further, in the second modification of the first embodiment shown in FIG. 10, the folding line N1 is not formed in the spring portion 35A, and the folding line N2 is not formed in the spring portion 35B. Therefore, in the spring portion 35A, the second exterior member 6 extends from the bending line M1 to the outer edge E2 toward the bottom wall 7 in the thickness direction of the battery 1 . In the spring portion 35B, the second exterior member 6 extends from the bending line M2 to the outer edge E2 toward the bottom wall 7 in the thickness direction of the battery 1 .

10, in the configuration in which the spring portion 35A extends from the bending line M1 to the outer edge E2 of the second exterior member 6 toward the side where the bottom wall 7 is located, the spring portion 35A is bent. Another folding line may be formed between the line M1 and the outer edge E2 of the second covering member 6 . In this case, the bending line extends along the vertical direction of the battery 1 . The bending line changes the bending angle of the spring portion 35A with respect to the extending portion of the second exterior member 6 from the opening edge 15 to the bending line M1. 10, the spring portion 35B extends from the bending line M2 to the outer edge E2 of the second exterior member 6 toward the side where the bottom wall 7 is located. Another folding line may be formed between the line M2 and the outer edge E2 of the second covering member 6 . In this case, the bending line extends along the lateral direction of battery 1 . The bending line changes the bending angle of the spring portion 35B with respect to the extending portion of the second exterior member 6 from the opening edge 15 to the bending line M2.

Moreover, in the third modification of the first embodiment of FIG. 11, each of the spring portions 35A, 35B is formed from both the flange 13 and the second exterior member 6. As shown in FIG. In this modification, both the flange 13 and the second exterior member 6 are bent at the bending line M1. In the spring portion 35A, the flange 13 extends from the bending line M1 to the outer edge E1 toward the bottom wall 7 in the thickness direction of the battery 1, and the second exterior member 6 extends along the bending line. It extends from M1 to the outer edge E2 toward the side where the bottom wall 7 is located in the thickness direction of the battery 1 . Moreover, in this modification, both the flange 13 and the second exterior member 6 are bent at the bending line M2. In the spring portion 35B, the flange 13 extends from the bending line M2 to the outer edge E1 toward the bottom wall 7 in the thickness direction of the battery 1, and the second exterior member 6 extends along the bending line. It extends from M2 to the outer edge E2 toward the side where the bottom wall 7 is located in the thickness direction of the battery 1 .

In addition, in a configuration in which the spring portion 35A is formed from both the flange 13 and the second exterior member 6 as in the modification of FIG. 11, the spring portion 35A may be formed with the welded portion 30. In this case, a welded portion 30 is formed between the bending line M1 and the outer edge E1 of the flange 13 , that is, between the bending line M1 and the outer edge E2 of the second exterior member 6 . In addition, in a configuration in which the spring portion 35B is formed from both the flange 13 and the second exterior member 6 as in the modification of FIG. 11, the welded portion 30 may be formed in the spring portion 35B. In this case, the welded portion 30 is formed between the bending line M2 and the outer edge E1 of the flange 13 , that is, between the bending line M2 and the outer edge E2 of the second exterior member 6 .

Also, in one variation, each of the spring portions 35A, 35B is formed from the flange 13 only. In this case, in each of the spring portions 35A and 35B, the flange 13 protrudes outward from the outer edge E2 of the second exterior member 6. As shown in FIG. Spring portions 35A and 35B are formed from portions of the flange 13 protruding from the outer edge E2 of the second exterior member 6. As shown in FIG. When each of the spring portions 35A and 35B is formed only from the flange 13, the thickness of the first exterior member 5 is preferably thick to some extent. It is preferably thicker than the thickness of the exterior member 6 of 2.

Also, each of the bent portions 41A and 41B may be formed from both the flange 13 and the second exterior member 6, or may be formed from the flange 13, similarly to the spring portions 35A and 35B. Moreover, when the bent portion 41A is formed from both the flange 13 and the second exterior member 6, the welded portion 30 may be formed in the bent portion 41A. Similarly, when the bent portion 41B is formed from both the flange 13 and the second exterior member 6, the welded portion 30 may be formed at the bent portion 41B.

Each of the spring portions 35A, 35B and the bent portions 41A, 41B can be formed from at least one of the flange 13 and the second exterior member 6, as described above. However, from the viewpoint of reducing labor and the like in manufacturing the battery 1, it is preferable that each of the spring portions 35A and 35B and the bent portions 41A and 41B is formed only from the second exterior member 6. FIG.

Further, in the fourth modification of the first embodiment shown in FIG. 12, the bent portions 41A and 41B are not formed in the battery 1. As shown in FIG. In this modification, the battery 1 does not have the bending lines M3 and M4. In the range where the side wall 8B extends in the circumferential direction of the opening 12, each of the flange 13 and the second exterior member 6 extends laterally outward from the opening edge 15 to the outer edge (E1; E2). deferred. In addition, in the range where the side wall 9B extends in the circumferential direction of the opening 12, each of the flange 13 and the second exterior member 6 extends from the opening edge 15 to the outer edge (E1; E2) outward in the longitudinal direction. deferred. In the battery 1 of this modified example, an end (reference end) P1 on the side opposite to the side where the spring portion 35A protrudes in the lateral direction is formed by the outer edge E1 of the flange 13 and the outer edge E2 of the second exterior member 6. be. In the battery 1 , an end P<b>2 opposite to the side where the spring portion 35</b>B protrudes in the vertical direction is formed by the outer edge E<b>1 of the flange 13 and the outer edge E<b>2 of the second exterior member 6 .

In the above-described embodiments and the like, the spring portion (first spring portion) 35A is arranged laterally on the side where the terminal (first terminal) 27A protrudes with respect to the side walls (8A, 8B, 9A, 9B). However, it is not limited to this. In one modification, the spring portion (first spring portion) 35A is arranged in the lateral direction opposite to the side from which the terminal (first terminal) 27A protrudes, with respect to the side walls (8A, 8B, 9A, 9B). protrude. That is, the spring portion (first spring portion) 35A protrudes with respect to the side walls (8A, 8B, 9A, 9B) in the lateral direction on the side where the terminal (second terminal) 27B protrudes. In this case also, the spring portion (first spring portion) 35A is elastically deformed by external force acting on the spring portion (first spring portion) 35A. Then, due to the elastic deformation of the spring portion 35A, a repulsive force having a force component in the side opposite to the side where the spring portion 35A protrudes from the side walls (8A, 8B, 9A, 9B) in the horizontal direction is elastically deformed. As a force reaction, it acts on the battery 1 including the exterior part 3 .

In addition, although the terminals 27A and 27B protrude from the outer surfaces of the side walls (8A, 8B, 9A and 9B) in the lateral direction opposite to each other in the above-described embodiments and the like, the present invention is not limited to this. In a fifth variant of the first embodiment shown in FIG. 13, both terminals 27A, 27B are attached to the outer surface of side wall 8B. Thus, the terminals 27A, 27B project laterally on the same side relative to each other at the outer surfaces of the side walls (8A, 8B, 9A, 9B). In this modified example, a spring portion 35A is formed in a range in which the side wall 8A extends in the circumferential direction of the opening 12. As shown in FIG. A bent portion 41A is formed in a range in which the side wall 8B extends in the circumferential direction of the opening 12. As shown in FIG.

Because of the configuration as described above, in this modified example, the spring portion (first spring portion) 35A is located on the lateral side from which the terminal (first terminal) 27A and the terminal (second terminal) 27B protrude. opposite to the side walls (8A, 8B, 9A, 9B). The bent portion 41A protrudes with respect to the side walls (8A, 8B, 9A, 9B) in the lateral direction on the side where the terminals 27A, 27B protrude. In addition, in the battery 1 of this modified example, an end (reference end) P1 on the side opposite to the side where the spring portion 35A protrudes in the lateral direction is formed by the end surface 42A of the bent portion 41A. In this modified example as well, the spring portion (first spring portion) 35A is elastically deformed when force acts on the spring portion (first spring portion) 35A from the outside. Then, due to the elastic deformation of the spring portion 35A, a repulsive force having a force component in the side opposite to the side where the spring portion 35A protrudes from the side walls (8A, 8B, 9A, 9B) in the horizontal direction is elastically deformed. As a force reaction, it acts on the battery 1 including the exterior part 3 .

In addition, in the configuration in which the terminals 27A and 27B protrude to the same side in the lateral direction as in the modification of FIG. terminal) 27A and the terminal (second terminal) 27B may be provided on the protruding side. In this case also, the spring portion (first spring portion) 35A is elastically deformed by external force acting on the spring portion (first spring portion) 35A. Then, due to the elastic deformation of the spring portion 35A, a repulsive force having a force component in the side opposite to the side where the spring portion 35A protrudes from the side walls (8A, 8B, 9A, 9B) in the horizontal direction is elastically deformed. As a force reaction, it acts on the battery 1 including the exterior part 3 .

Also, in a modification, the spring portion (second spring portion) 35B may not be provided. However, in this case also, the spring portion (first spring portion) 35A is provided. Then, due to the elastic deformation of the spring portion 35A, a repulsive force having a force component in the side opposite to the side where the spring portion 35A protrudes from the side walls (8A, 8B, 9A, 9B) in the horizontal direction is elastically deformed. As a force reaction, it acts on the battery 1 including the exterior part 3 .

Moreover, in a modification, a plurality of electrode groups may be housed in the internal space 11 . Moreover, in another modification, the second exterior member 6 is formed in a box-tube shape with a bottom similar to that of the first exterior member 5 instead of being substantially plate-shaped. In this case, the second exterior member 6 is also formed with a bottom wall, side walls and flanges. Then, the flange 13 of the first exterior member 5 and the flange of the second exterior member 6 are hermetically welded together at the welding portion 30 . In the battery 1 of this modification as well, the flange 13 and the second exterior member 6 are airtightly welded by the welding portion 30 along the entire circumference of the opening 12 in the circumferential direction. An internal space 11 in which the electrode group 10 is accommodated is sealed from the outside of the exterior part 3 .

In the battery (1) such as the above-described embodiment, the first terminal (27A) and the second terminal (27B), which are a pair of electrode terminals, are laterally on the same side with respect to each other, or with respect to each other. on the opposite side at the outer surface of the sidewalls (8A, 8B, 9A, 9B). At least one of the flange (13) and the second exterior member (6), the spring portion (35A) protrudes from the opening edge (15) of the flange (13) and the second exterior member (6). formed from The spring part (35A) is provided with side walls (8A, 8B, 9A, 9B). The elastic deformation of the spring portion (35A) due to the action of an external force from the outside causes the spring portion (35A) to move in the lateral direction to the opposite side to the side wall (8A, 8B, 9A, 9B). A repulsive force having a force component acts on the first exterior member (5) and the second exterior member (6) as a reaction to the elastic force of the spring portion (35A).

[Battery assembly]
Next, a battery assembly including any of the batteries of the above-described embodiments (first embodiment and modifications thereof) will be described. A battery assembly includes any of the batteries, such as the previous embodiments, and a case that houses the batteries.

(Second embodiment)
FIG. 14 shows a battery assembly 50 according to the second embodiment as an example of the battery assembly. As shown in FIG. 14 , battery assembly 50 includes battery 1 and case 51 . In this embodiment, the battery 1 has the same configuration as that of the first embodiment. Here, in the battery assembly 50, similarly to the battery 1, the vertical direction (direction indicated by arrows X1 and X2), the horizontal direction (direction indicated by arrows Y1 and Y2), and the thickness direction (directions indicated by arrows Z1 and arrows Y2) direction indicated by Z2).

15 and 16 show the case 51, in which the directions of viewing the case 51 are different from each other. 17 shows cross section A2 of FIG. 14, which shows a cross section perpendicular or substantially perpendicular to the lateral direction in the battery assembly 50. As shown in FIG. 18 shows an enlarged view of the region H3 of FIG. 17, and FIG. 19 shows an enlarged view of the region H4 of FIG. As shown in FIGS. 14 to 19, the case 51 has a case bottom wall 52 and two pairs of case side walls 53A, 53B, 55A and 55B, and is formed in a substantially rectangular box shape with a bottom. In case 51, storage space 61 is defined by case bottom wall 52 and case side walls 53A, 53B, 55A, and 55B. The battery 1 is housed in the housing space 61 . In the case 51, the side where the storage space 61 is located is defined as the inside, and the side opposite to the side where the storage space 61 is located is defined as the outside.

In the case 51 , a case opening 62 is formed as an opening of the storage space 61 on the side opposite to the case bottom wall 52 in the thickness direction. In the case side walls 53A, 53B, 55A, 55B, an opening edge 63 of the case opening 62 is formed at the end opposite to the case bottom wall 52 in the thickness direction. An opening edge 63 of the case opening 62 extends along the circumferential direction of the case opening 62 . In this embodiment, the case opening 62 is formed in a substantially rectangular shape, and the opening edge 63 forms a substantially rectangular outer edge. Further, the storage space 61 opens toward one side (the arrow Z1 side) in the thickness direction at the case opening 62 . The opening surface of the case opening 62 is parallel or substantially parallel to the vertical and horizontal directions.

In the case 51, each of the pair of case side walls 53A and 53B extends along the vertical direction and continues in the vertical direction from the case side wall 55A to the case side wall 55B. Each of the pair of case side walls 55A and 55B extends in the horizontal direction and continues in the horizontal direction from the case side wall 53A to the case side wall 53B. The case side walls 53A and 53B face each other across the storage space 61 and are arranged apart in the lateral direction. The case side walls 55A and 55B face each other across the storage space 61 and are spaced apart in the vertical direction. Further, each of the case side walls 53A, 53B, 55A, 55B extends from the case bottom wall 52 toward the case opening 62. As shown in FIG.

The battery assembly 50 is formed such that the lateral dimension between the case side walls 53A and 53B, i.e., the lateral dimension of the storage space 61, varies little from case to case 51 (for each battery assembly 50). . Therefore, in each of the manufactured battery assemblies 50, the dimension between the case side walls 53A and 53B is the same or substantially the same as the predetermined reference dimension L0. In addition, in the battery assembly 50 of the present embodiment, the vertical dimension between the case side walls 55A and 55B, that is, the vertical dimension of the storage space 61 also varies for each case 51 (for each battery assembly 50). formed without.

In the case 51, a recess 56A is provided in the case side wall 53A, and a recess 56B is provided in the case side wall 53B. In each of the recesses 56A and 56B, the opening edge 63 is recessed toward the side where the case bottom wall 52 is located. Therefore, the dimension in the thickness direction of the battery assembly 50 from the case bottom wall 52 to the opening edge 63 at each of the recesses 56A and 56B is the same as that from the case bottom wall 52 to the opening edge 63 at portions other than the recesses 56A and 56B. It is smaller than the dimension in the thickness direction of the battery assembly 50 up to . In this embodiment, the recess 56A is arranged at the center or approximately the center of the case side wall 53A in the longitudinal direction of the battery assembly 50, and the recess 56B is located at the center or approximately the center of the case side wall 53B in the longitudinal direction of the battery assembly 50. placed in position.

A pair of holes (first connecting portions) 57A are formed in the case side wall 53A, and a pair of holes (second connecting portions) 57B are formed in the case side wall 53B. Each of the holes 57A and 57B penetrates the case 51 from the opening edge 63 to the case bottom wall 52 in the thickness direction. Also, each of the holes 57A and 57B extends along the thickness direction of the battery assembly 50 . In this embodiment, each of the holes 57A and 57B is positioned at a corresponding one of the four corners of the substantially rectangular shape at the opening edge 63 forming the outer edge of the substantially rectangular shape, and the other three holes (57A , 57B) are formed at different corners. Holes 57A and 57B are positions for connecting battery assembly 50 to other battery assemblies. Battery assembly 50 is connected to other battery assemblies, for example, by inserting bolts 72 (see FIGS. 22 and 23 described later) through holes 57A and 57B, respectively.

Each of the holes (first holes) 57A is formed laterally outward with respect to the inner surface of the case side wall 53A. In addition, the pair of holes (first connecting portions) 57A are located apart from each other in the vertical direction. In this embodiment, one of the holes 57A is formed at one end of the case side wall 53A in the longitudinal direction of the battery assembly 50, and the other of the holes 57A is formed in the other end of the case side wall 53A in the longitudinal direction of the battery assembly 50. formed in However, the pair of holes 57A are not misaligned or almost misaligned with respect to each other in the lateral direction of the battery assembly 50 .

Each of the holes (second holes) 57B is formed laterally outward with respect to the inner surface of the case side wall 53B. Also, the pair of holes (second connecting portions) 57B are positioned apart from each other in the vertical direction. In this embodiment, one of the holes 57B is formed at one end of the case side wall 53B in the longitudinal direction of the battery assembly 50, and the other of the holes 57B is formed in the other end of the case side wall 53B in the longitudinal direction of the battery assembly 50. formed in However, the pair of holes 57B are not misaligned or almost misaligned with respect to each other in the lateral direction of the battery assembly 50 .

In the battery assembly 50 of the present embodiment, the distance from each of the holes (first connecting portions) 57A to the inner surface of the case side wall 53A in the lateral direction hardly varies from case to case 51 (for each battery assembly 50). It is formed. The battery assembly 50 is formed such that the distance from each of the holes (second connecting portions) 57B to the inner surface of the case side wall 53B in the lateral direction is almost uniform for each case 51 (for each battery assembly 50). be. In this embodiment, the distance from each of the holes (first connecting portions) 57A to the inner surface of the case side wall 53A in the horizontal direction is the same as the distance from each of the holes (second connecting portions) 57B to the case side wall in the horizontal direction. It becomes the same or substantially the same as the distance to the inner surface of 53B.

A non-circular cross-sectional portion 58A is formed in each of the holes 57A, and a non-circular cross-sectional portion 58B is formed in each of the holes 57B. In each of the holes 57A, a non-circular cross-sectional portion 58A extends along the thickness direction of the battery assembly 50 from the outer surface of the case bottom wall 52 toward the side where the opening edge 63 is located. In each of the holes 57B, a non-circular cross-sectional portion 58B extends along the thickness direction of the battery assembly 50 from the outer surface of the case bottom wall 52 toward the side where the opening edge 63 is located. The cross-sectional shape of each hole 57A is circular or substantially circular at portions other than the non-circular cross-sectional portion 58A, and is non-circular such as polygonal at the non-circular cross-sectional portion 58A. Similarly, the cross-sectional shape of each hole 57B is circular or substantially circular at portions other than the non-circular cross-sectional portion 58B, and is non-circular such as polygonal at the non-circular cross-sectional portion 58B. In one example such as FIG. 14, the cross-sectional shape of each of the holes 57A and 57B is hexagonal or substantially hexagonal in the non-circular cross-sectional portions (58A; 58B). Also, in each of the holes 57A, the non-circular cross-sectional portion 58A has a larger cross-sectional area than the other portions, and in each of the holes 57B, the non-circular cross-sectional portion 58B has a larger cross-sectional area than the other portions.

Further, the case 51 is provided with a projecting portion 65 on the outer surface of the case bottom wall 52 . The projecting portion 65 projects in the thickness direction of the battery assembly 50 to the side opposite to the side where the case opening 62 opens. In an example such as FIG. 16 , the projecting portion 65 is formed over most of the outer surface of the case bottom wall 52, and on the outer surface of the case bottom wall 52, except for the outer edge of the case bottom wall 52 and its vicinity, A protrusion 65 is formed. The holes 57A and 57B are formed on the outer surface of the case bottom wall 52 at portions other than the projecting portion 65. As shown in FIG.

In the storage space 61, the side wall 8A of the battery 1 faces the case side wall 53A across the spring portion 35A, and the side wall 8B of the battery 1 faces the case side wall 53B across the bent portion 41A. Side wall 9A of battery 1 faces case side wall 55A across spring portion 35B, and side wall 9B of battery 1 faces case side wall 55B across bent portion 41B. In the storage space 61 , the second exterior member 6 of the battery 1 contacts the inner surface of the case bottom wall 52 . In addition, the outer surface of the bottom wall 7 of the battery 1 faces the side where the case opening 62 opens in the thickness direction. The terminal (first terminal) 27A is arranged in a range where the recess 56A is formed in the circumferential direction of the case opening 62, and the terminal (second terminal) 27B is arranged in the circumferential direction of the case opening 62 so that the recess 56B is formed. Placed in the formed range. Therefore, the terminal 27A is exposed to the outside of the case 51 through the recess 56A, and the terminal 27B is exposed to the outside of the case 51 through the recess 56B.

Since the battery 1 is stored as described above, in the storage space 61, the spring portion 35A is elastically deformed by an external force from the case side wall 53A. When the spring portion 35A is elastically deformed, a repulsive force having a force component in the lateral direction opposite to the side where the spring portion 35A protrudes from the side wall 8A is released from the case side wall 53A into the battery as a reaction to the elastic force. 1. Due to the repulsive force from the case side wall 53A, the battery 1 contacts the case side wall 53B at the end surface 42A of the bent portion 41A. That is, the battery 1 contacts the case side wall 53B at the end (reference end) P1 on the side opposite to the side where the spring portion 35A protrudes in the horizontal direction. At this time, the end (first reference end) P1 of the battery 1 contacts the contact position (first contact position) T1 on the case side wall 53B.

In addition, in the storage space 61, the spring portion 35B is elastically deformed by an external force from the case side wall 55A. Due to the elastic deformation of the spring portion 35B, a repulsive force having a force component in the direction opposite to the side where the spring portion 35B protrudes from the side wall 9A in the vertical direction is released from the case side wall 55A as a reaction to the elastic force. 1. Due to the repulsive force from the case side wall 55A, the battery 1 contacts the case side wall 55B at the end surface 42B of the bent portion 41B. That is, the battery 1 contacts the case side wall 55B at the end P2 opposite to the side where the spring portion 35B protrudes in the vertical direction. At this time, the end (second reference end) P2 of the battery 1 comes into contact with the contact position (second contact position) T2 on the case side wall 55B.

As described above in the first embodiment, in each of the manufactured batteries 1, the terminal (first terminal) extends from the end P1 (end surface 42A) opposite to the side where the spring portion 35A projects in the lateral direction. 27A to the terminal-side contact surface 37A is the same or substantially the same as the predetermined first distance L1. In each of the manufactured batteries 1, the distance from the end P1 (end surface 42A) to the terminal-side contact surface 37B of the terminal (second terminal) 27B in the lateral direction is equal to or substantially equal to the predetermined second distance L2. be the same. In the battery assembly 50 of the present embodiment, the repulsive force against the elastic force of the spring portion 35A causes the battery 1 to move toward the case at the end (reference end) P1 opposite to the side where the spring portion 35A protrudes in the lateral direction. It abuts on the side wall 53B. Therefore, in each of the manufactured battery assemblies 50, the terminal side contact surface 37A of the terminal (first terminal) 27A from the contact position T1 of the end (reference end) P1 of the battery 1 to the case side wall 53B in the lateral direction. up to is the same as or substantially the same as the predetermined first distance L1. In each of the manufactured battery assemblies 50, the terminal side contact surface 37B of the terminal (second terminal) 27B extends from the contact position T1 of the end (reference end) P1 of the battery 1 to the case side wall 53B in the lateral direction. up to is the same as or substantially the same as the predetermined second distance L2.

Since the battery assembly 50 is formed as described above, in the battery assembly 50 of the present embodiment, the distances from the case side wall 53B to the terminals 27A and 27B are formed with little variation for each battery assembly 50. . Therefore, the battery assembly 50 of the present embodiment is formed with little variation in the positional relationship of the terminals 27A and 27B with respect to the case 51 in the lateral direction for each battery assembly 50 . Therefore, in the present embodiment, variation in the positional relationship between the case 51 and the battery 1 in the lateral direction for each battery assembly 50 is suppressed. In addition, in the present embodiment, since the battery 1 is provided with the spring portion 35B similar to the spring portion 35A, the flapping of each battery assembly 50 regarding the positional relationship between the case 51 and the battery 1 in the vertical direction is also suppressed. .

As described above, in the present embodiment, the batteries 1 are arranged in the housing space 61 with high accuracy in the case 51 in each of the battery assemblies 50 without variation among the battery assemblies 50 . That is, the battery assembly 50 is provided in which the batteries 1 are accurately arranged with respect to the case 51 in the storage space 61 .

In the present embodiment, the bent portion 41A is formed in the battery 1, and in the battery 1, the end (reference end) P1 on the side opposite to the side where the spring portion 35A protrudes in the lateral direction is the end face 42A of the bent portion 41A. formed by Then, the end surface 42A of the bent portion 41A abuts the case side wall 53B with its surface. Therefore, in the battery 1, the end (reference end) P1 on the side opposite to the side where the spring portion 35A protrudes in the horizontal direction reliably contacts the case side wall 53A. Therefore, the accuracy of the lateral positional relationship between the case 51 and the battery 1 is further improved. Further, in the present embodiment, since the bent portion 41B similar to the bent portion 41A is formed in the battery 1, the accuracy of the positional relationship between the case 51 and the battery 1 in the vertical direction is further improved.

(Modification of Second Embodiment)
Although the battery 1 of the first embodiment is used in the second embodiment, the battery 1 used in the battery assembly 50 is a battery in which the spring portion 35A is formed as in the above-described embodiment. I wish I had. By using the battery 1 provided with the spring portion 35A, the positional relationship of the terminals 27A and 27B with respect to the case 51 in the horizontal direction of the battery assembly 50 is almost the same as in the second embodiment. Formed without variation. Therefore, variations in the lateral positional relationship between the case 51 and the battery 1 for each battery assembly 50 are suppressed. As a result, the batteries 1 in the storage space 61 are accurately arranged with respect to the case 51 in each of the battery assemblies 50 without variation among the battery assemblies 50 .

In addition, in the first modification of the second embodiment shown in FIG. 20, projections 66 (four in this modification) are provided on the outer surface of the case bottom wall 52 instead of the protrusions 65 . Each projection 66 protrudes in the thickness direction of battery assembly 50 on the side opposite to the side where case opening 62 opens. In this modification, each of the projections 66 is positioned at a corresponding one of the four corners of the substantially rectangular shape on the outer surface of the substantially rectangular case bottom wall 52, and the other three projections (corresponding to 66 3) are formed at different corners. Also, each of the protrusions 66 is arranged inside the holes 57A and 57B in the lateral direction of the battery assembly 50 .

Also, in some variations, both the protrusion 65 and the protrusion 66 may be provided on the outer surface of the case bottom wall 52 . In this case, a protrusion 66 is formed on the protruding end surface of the protruding portion 65 . Each of the protrusions 66 further protrudes from the protruding end surface of the protruding portion 65 on the side opposite to the side where the case opening 62 opens in the thickness direction of the battery assembly 50 .

Further, in the second modification of the second embodiment shown in FIG. 21, the distance from each hole (first connecting portion) 57A in the horizontal direction to the inner surface of the case side wall 53A is equal to the hole ( The distance from each of the second connecting portions 57B to the inner surface of the case side wall 53B is different. However, in the battery assembly 50 of this modified example as well, the distance from each of the holes (first connecting portions) 57A to the inner surface of the case side wall 53A in the lateral direction varies substantially for each case 51 (for each battery assembly 50). formed without. The battery assembly 50 is formed such that the distance from each of the holes (second connecting portions) 57B to the inner surface of the case side wall 53B in the lateral direction is almost uniform for each case 51 (for each battery assembly 50). be.

In this modification, in each of the battery assemblies 50 to be manufactured, the distance from each hole (first connecting portion) 57A to the inner surface of the case side wall 53A in the lateral direction is equal to or substantially equal to the predetermined third distance α1. become identical. In each of the manufactured battery assemblies 50, the distance from each of the holes (second connecting portions) 57B to the inner surface of the case side wall 53B in the lateral direction is the same or substantially the same as the predetermined fourth distance α2. . In this modification, the third distance α1 is smaller than the fourth distance α2. The difference between the third distance α1 and the fourth distance α2 is the same or substantially the same as the predetermined magnitude γ. The predetermined magnitude γ is a value based at least on the first distance L1 and the second distance L2 described above. In this modification, the predetermined size γ satisfies the relation γ=α2−α1=L0−(L1+L2) with respect to the reference dimension L0, the first distance L1 and the second distance L2.

In a modification, the bottom wall 7 of the first exterior member 5 of the battery 1 abuts the inner surface of the case bottom wall 52 in the housing space 61 of the case 51 . In addition, the outer surface of the second exterior member 6 of the battery 1 faces the side where the case opening 62 opens in the thickness direction. However, even in this modified example, in the storage space 61, the side wall 8A of the battery 1 faces the case side wall 53A with the spring portion 35A interposed therebetween.

In the battery assembly (50) of the above-described embodiments and the like, any one of the batteries (1) of the first embodiment and its modification is housed in the housing space (61) of the case (51). In the storage space (61), repulsive force from the case side walls (53A, 53B, 55A, 55B) acts on the battery (1) as a reaction to the elastic force of the spring portion (35A). Then, in the storage space (61), the battery (1) is moved laterally to the end opposite to the side where the spring portion (35A) protrudes due to the repulsive force from the case side walls (53A, 53B, 55A, 55B). The reference end (P1) of .theta.

[Battery module]
Next, the battery module will be explained. The battery module includes a plurality of battery assemblies, each of which has the same configuration as any of the battery assemblies of the above-described embodiments (second embodiment and modifications thereof).

(Third embodiment)
22 and 23 show a battery module 70 according to the third embodiment as an example of the battery module. As shown in FIGS. 22 and 23, the battery module 70 includes a plurality of battery assemblies 50A-50H. In this embodiment, each of the plurality of battery assemblies 50A to 50H uses the battery assembly 50 having the same configuration as in the second embodiment. Therefore, each of the battery assemblies 50A to 50H includes a battery 1 having the same configuration as in the first embodiment and a case 51 having the same configuration as in the second embodiment. Note that FIG. 23 shows the battery module 70 with some parts disassembled.

In this embodiment, in the battery module 70, a plurality of battery assemblies 50A-50H are stacked. In the battery module 70, the stacking direction of the battery assemblies 50A to 50H (the directions indicated by the arrows Z3 and Z4) is the arrangement direction in which the battery assemblies 50A to 50H are arranged. In this embodiment, the battery assemblies 50A to 50H are stacked such that the vertical direction and the horizontal direction of each of the battery assemblies 50A to 50H (battery 1) are perpendicular or substantially perpendicular (cross) to the stacking direction. That is, the battery assemblies 50A to 50H are stacked such that the thickness direction of each of the battery assemblies 50A to 50H (battery 1) matches or substantially matches the stacking direction.

Here, in the battery module 70, a first direction perpendicular or substantially perpendicular (intersecting) to the stacking direction (directions indicated by arrows Y3 and Y4) and both the stacking direction and the first direction defines a vertical or substantially vertical (intersecting) second direction (direction indicated by arrows X3 and X4). Each of the battery assemblies 50A to 50H (battery 1) is arranged such that the lateral direction matches or substantially matches the first direction and the vertical direction matches or substantially matches the second direction. Two of the battery assemblies 50A to 50H that are adjacent to each other (stacked) are called battery assemblies 50α and 50β. In one example of FIGS. 22 and 23, battery assembly (first battery assembly) 50α is any one of battery assemblies 50A to 50G, and battery assembly (second battery assembly) 50β is battery assembly 50B to 50G. A corresponding one in 50H.

FIG. 24 shows the stacking state of battery assemblies 50α and 50β that are stacked next to each other. FIG. 24 shows a cross section perpendicular or substantially perpendicular to the second direction and passing through the spring portion 35A and the bent portion 41A of each of the battery assemblies 50α and 50β. Therefore, in FIG. 24, each of the battery assemblies 50α, 50β is shown in cross section perpendicular or substantially perpendicular to the longitudinal direction and passing through the spring portion 35A and the bent portion 41A. As shown in FIGS. 22 to 24, in this embodiment, the case bottom wall 52 of the case 51 of the battery assembly (second battery assembly) 50β covers the case opening 62 of the battery assembly (first battery assembly) 50α. It faces the bottom wall 7 of the battery 1 of the battery assembly 50α via the battery assembly 50α.

In the battery module 70, the battery assemblies 50α and 50β are arranged in both the first direction and the second direction, that is, in the direction perpendicular or substantially perpendicular (intersecting) to the stacking direction without being displaced with respect to each other. , or arranged with little deviation. Further, the areas surrounded by the outer surfaces of the case side walls 53A, 53B, 55A, 55B and the storage space 61 are offset in both the first direction and the second direction between the battery assemblies 50α, 50β. None, or almost no deviation.

In addition, the spring portion 35A of the battery assembly (first battery assembly) 50α moves the battery assembly (first battery assembly) with respect to the electrode group 10 of the battery assemblies 50α and 50β in the first direction (lateral direction of the battery assemblies 50α and 50β). It is located on the side opposite to the side where the spring portion 35A of the second battery assembly 50β is located. Therefore, the spring portion 35A of the battery assembly 50α is located on the side where the bent portion 41A of the battery assembly 50β is located with respect to the electrode group 10 of the battery assemblies 50α and 50β in the first direction. Therefore, in the battery 1 of the battery assembly 50β, if the end (reference end) P1 of the battery 1 of the battery assembly 50β on the side opposite to the projecting side of the spring portion 35A in the lateral direction is defined as described above, the end P1 of the battery 1 of the battery assembly 50β is , on the side where the spring portion 35A of the battery assembly 50α is positioned with respect to the electrode groups 10 of the battery assemblies 50α and 50β in the first direction.

In the battery module 70, the holes (second connecting portions) 57B of the battery assemblies 50β are aligned with the electrode groups 10 of the battery assemblies 50α and 50β in the first direction (lateral direction of the battery assemblies 50α and 50β). It is located on the side where the spring portion 35A and the hole (first connecting portion) 57A of the assembly 50α are located. Then, each of the holes 57A of the battery assembly (first battery assembly) 50α is coaxial or substantially coaxial with the corresponding one of the holes 57B of the battery assembly (second battery assembly) 50β. communicates with the corresponding one of 57B. In addition, the hole (first connecting portion) 57A of the battery assembly 50β connects the spring portion 35A and the hole (first connecting portion) of the battery assembly 50α to the electrode groups 10 of the battery assemblies 50α and 50β in the first direction. part) 57A is located on the side opposite to the side where 57A is located. That is, the hole 57A of the battery assembly 50β is positioned on the side of the electrode group 10 in the first direction where the hole (second connecting portion) 57B of the battery assembly 50α is positioned. Then, each of the holes 57B of the battery assembly (first battery assembly) 50α is coaxial or substantially coaxial with the corresponding one of the holes 57A of the battery assembly (second battery assembly) 50β. communicates with the corresponding one of 57A.

The battery module 70 also includes a substantially rectangular plate-shaped lid 71 . Lid 71 is stacked together with battery assemblies 50A-50H. The lid 71 is stacked on the side opposite to the side where the battery assemblies 50A to 50G are located with respect to the stacking direction with respect to the battery assembly 50H. Thus, among battery assemblies 50A-50H, battery assembly 50H is positioned most proximal to lid 71 and battery assembly 50A is positioned most distal to lid 71. FIG. The lid 71 faces the bottom wall 7 of the battery 1 of the battery assembly 50H through the case opening 62 of the battery assembly 50H.

Lid 71 also includes surfaces 73 and 75 . Each of the surfaces 73, 75 is formed in a substantially rectangular shape. The surface 73 faces the side opposite to the side on which the battery assemblies 50A to 50H are positioned with respect to the stacking direction. The surface 75 faces the side where the battery assemblies 50A to 50H are located, and faces the side opposite to the side to which the surface 73 faces in the stacking direction. The lid 71 is also formed with holes 76 (four in this embodiment). Each hole 76 extends through lid 71 from surface 73 to surface 75 . In this embodiment, each of the holes 76 is located at a corresponding one of the four corners of the substantially rectangular shape in the surface 73 of the substantially rectangular lid 71, and the other three holes (the corresponding three of the 76). ) are formed at different corners. Each of the holes 76 of the lid 71 is coaxial or nearly coaxial with a corresponding one of the holes 57A, 57B of the battery assembly 50H and communicates with a corresponding one of the holes 57A, 57B of the battery assembly 50H.

In addition, the battery module 70 is provided with bolts 72 and nuts 77 (four each in this embodiment). Each bolt 72 is inserted through a corresponding one of the holes 76 in the lid 71 . Also, each of the bolts 72 is inserted through a corresponding one of the holes 57A, 57B of the case 51 in each of the battery assemblies 50A-50H. Each of the nuts 77 engages with a corresponding one of the bolts 72 at a corresponding one of the non-circular cross-sections (58A; 58B) of the holes 57A, 57B in the battery assembly 50A located most distally with respect to the lid 71. screw together. Each nut 77 is located in a corresponding one of the non-circular cross-sections (58A; 58B) of the holes 57A, 57B of the battery assembly 50A, thereby aligning the axis of the central axis of the bolt (corresponding one of 72) with which it is threaded. Rotation of each of the nuts 77 about the circumference is restricted.

As described above, in the battery module 70 of this embodiment, the battery assemblies 50A to 50H and the lid 71 are connected by the bolts 72 and nuts 77. FIG. Thus, in each of battery assemblies 50A-50H, hole (first connection) 57A and hole (second connection) 57B connect to other battery assemblies (the corresponding seven of 50A-50H) and lid 71. becomes the connection position of In lid 71, holes 76 are connecting positions to battery assemblies 50A to 50H. In addition, since the battery assemblies 50A to 50H and the lid 71 are connected by the bolts 72 and the nuts 77 as described above, in the battery module 70, the battery assemblies 50A to 50H and the lid 71 are tightened (compressed) in the stacking direction. ).

By tightening the battery assemblies 50A to 50H and the lid 71 in the stacking direction as described above, in the battery assemblies 50α and 50β stacked adjacent to each other, the case 51 of the battery assembly (second battery assembly) 50β case bottom wall 52 interferes with the battery 1 of the battery assembly (first battery assembly) 50α. In this embodiment, the projecting portion 65 of the case bottom wall 52 of the battery assembly 50β abuts the bottom wall 7 of the battery 1 of the battery assembly 50α. As a result, a pressing force acts on the bottom wall 7 of the battery 1 of the battery assembly 50α from the projecting portion 65 of the case bottom wall 52 of the battery assembly 50β. When a pressing force acts on the battery 1 of the battery assembly 50α from the case bottom wall 52 of the battery assembly 50β, the movement of the battery 1 in the storage space 61 is restricted by friction in the battery assembly 50α. That is, in the battery assembly 50α, the movement of the batteries 1 in the directions (the first direction and the second direction) crossing the stacking direction causes the case bottom wall 52 of the battery assembly 50β and the batteries 1 of the battery assembly 50α to move. regulated by friction between As described above, in the present embodiment, the projecting portion 65 formed on the case bottom wall 52 of the battery assembly 50β serves as a restricting portion that restricts movement of the batteries 1 of the battery assembly 50α.

Also, the battery assemblies 50α and 50β stacked adjacent to each other are electrically connected by a bus bar 36, which is a connection member. Bus bar 36 is formed from a conductive material such as metal. FIG. 25 shows the configuration of the bus bar 36. As shown in FIG. FIG. 26 shows the electrical connection state of the battery assemblies 50α and 50β stacked adjacent to each other by the busbars 36. As shown in FIG. FIG. 26 shows a cross-section perpendicular or nearly perpendicular to the second direction and through terminals 27A and 27B of battery assemblies 50α and 50β, respectively. Accordingly, in FIG. 24, each of the battery assemblies 50α, 50β is shown in cross-section perpendicular or substantially perpendicular to the longitudinal direction and through terminals 27A, 27B.

As shown in FIGS. 23, 24, 26, etc., in the present embodiment, the terminal (first terminal) 27A of the battery assembly (first battery assembly) 50α is arranged in the first direction (battery assemblies 50α, 50β). lateral direction), the side opposite to the side where the terminal (first terminal) 27A and the spring portion 35A of the battery assembly (second battery assembly) 50β are located with respect to the electrode group 10 of the battery assemblies 50α and 50β located in Therefore, in the battery 1 of the battery assembly 50β, if the end (reference end) P1 of the battery 1 of the battery assembly 50β on the side opposite to the projecting side of the spring portion 35A in the lateral direction is defined as described above, the end P1 of the battery 1 of the battery assembly 50β is With respect to the first direction, the terminal (first terminal) 27A of the battery assembly 50α is located on the side of the electrode group 10 of the battery assemblies 50α and 50β. Terminal (second terminal) 27B of battery assembly 50β is positioned such that terminal (first terminal) 27A of battery assembly 50α is positioned with respect to electrode group 10 of battery assemblies 50α and 50β in the first direction. located on the side.

In this embodiment, the bus bar 36 connects the terminal (first terminal) 27A of the battery assembly (first battery assembly) 50α and the terminal (second terminal) 27B of the battery assembly (second battery assembly) 50β. electrically connect between As previously mentioned, terminals 27A and 27B have opposite electrical polarities with respect to each other. Therefore, the batteries 1 of the battery assemblies 50α, 50β are electrically connected in series by the busbar 36. As shown in FIG. In battery module 70, batteries 1 of battery assemblies 50A to 50H are electrically connected in series with each other. Bus bar 36 passes through recess 56A of case 51 of battery assembly 50α and through recess 56B of case 51 of battery assembly 50β.

Moreover, each of the battery assemblies 50A to 50H has the same configuration as the battery assembly 50 of the second embodiment. Therefore, in each of the battery assemblies 50α and 50β, the contact surface 37A of the terminal (first terminal) 27A from the contact position T1 of the end (reference end) P1 of the battery 1 to the case side wall 53B in the lateral direction. up to is the same as or substantially the same as the predetermined first distance L1. In each of the battery assemblies 50α and 50β, in the lateral direction, from the contact position T1 of the end (reference end) P1 of the battery 1 to the case side wall 53B to the terminal side contact surface 37B of the terminal (second terminal) 27B. is the same as or substantially the same as the predetermined second distance L2.

In this embodiment, the terminal (first terminal) 27A of the battery assembly (first battery assembly) 50α is arranged in the first direction (lateral direction of the battery assemblies 50α and 50β). There is a deviation from the terminal (second terminal) 27B of the battery assembly) 50β. The displacement of the terminal 27A of the battery assembly 50α with respect to the terminal 27B of the battery assembly 50β is the same or substantially the same as the predetermined amount γ. The predetermined size γ can be calculated in the same manner as in the modified example of FIG. 21 (second modified example of the second embodiment) described above. At least the value based on Therefore, the predetermined size γ satisfies the relation γ=L0−(L1+L2) with respect to the reference dimension L0, the first distance L1 and the second distance L2.

As shown in FIGS. 25 and 26 and the like, the busbar 36 includes connector portions 81A and 81B and a relay portion 83 that relays between the connector portions 81A and 81B. The connector portion (first connector portion) 81A is connected to the terminal (first terminal) 27A of the battery assembly (first battery assembly) 50α. The connector portion 81A includes a contact surface (first contact surface) 82A that contacts the terminal-side contact surface 37A of the terminal 27A of the battery assembly 50α. Also, the connector portion (second connector portion) 81B is connected to the terminal (second terminal) 27B of the battery assembly (second battery assembly) 50β. The connector portion 81B includes a contact surface (second contact surface) 82B that contacts the terminal-side contact surface 37B of the terminal 27B of the battery assembly 50β.

In the busbar 36, the contact surfaces 82A, 82B are parallel or substantially parallel to each other. Also, the contact surfaces 82A, 82B are spaced apart from each other in a direction perpendicular or substantially perpendicular to the contact surfaces 82A, 82B. The separation distance between the contact surfaces 82A and 82B is the terminal (first terminal) of the battery assembly (first battery assembly) 50α relative to the terminal (second terminal) 27B of the battery assembly (second battery assembly) 50β. It becomes the same or substantially the same as the deviation of 27A. Therefore, in each of the busbars 36, the separation distance between the contact surfaces 82A and 82B is the same or substantially the same as the above-mentioned predetermined size γ.

As described above, in this embodiment, the separation distance between the contact surfaces 82A and 82B of the bus bar 36 is the same or substantially the same as the displacement of the terminal 27A of the battery assembly 50α with respect to the terminal 27B of the battery assembly 50β. Therefore, in welding the bus bar 36 to the terminal (first terminal) 27A of the battery assembly (first battery assembly) 50α, the contact surface (first contact surface) 82A of the bus bar 36 is positioned on the terminal side of the terminal 27A. It is in surface contact with the contact surface 37A without a gap or almost without a gap. Similarly, in welding the bus bar 36 to the terminal (second terminal) 27B of the battery assembly (second battery assembly) 50β, the contact surface (second contact surface) 82B of the bus bar 36 is positioned on the terminal side of the terminal 27B. It is in surface contact with the contact surface 37B without a gap or almost without a gap. As a result, the contact surface 82A of the busbar 36 is properly welded to the terminal 27A of the battery assembly 50α, and the contact surface 82B of the busbar 36 is properly welded to the terminal 27B of the battery assembly 50β. Therefore, in this embodiment, the bus bar 36 to the terminal (first terminal) 27A of the battery assembly (first battery assembly) 50α and the terminal (second terminal) 27B of the battery assembly (second battery assembly) 50β workability is improved in the welding of

(Modification of the third embodiment)
Note that in the first modification of the third embodiment shown in FIG. 27, the battery assembly 50 having the same configuration as the example of FIG. 50H is used in the battery module 70 . That is, the battery assembly 50 in which the protrusion 66 is provided on the case bottom wall 52 of the case 51 instead of the protrusion 65 is used as the battery assemblies 50A to 50H in the battery module 70. FIG. In this modification as well, the battery assemblies 50A to 50H and the lid 71 are tightened in the stacking direction, so that the battery assemblies 50α and 50β that are stacked next to each other have a case of the battery assembly (second battery assembly) 50β. Case bottom wall 52 of 51 interferes with battery 1 of battery assembly (first battery assembly) 50α.

In this modification, the protrusion 66 of the case bottom wall 52 of the battery assembly 50β abuts the bottom wall 7 of the battery 1 of the battery assembly 50α and presses the bottom wall 7 of the battery 1 of the battery assembly 50α. As a result, portions of the bottom wall 7 of the battery 1 of the battery assembly 50α that are pressed by the projections 66 of the case bottom wall 52 of the battery assembly 50β are recessed inward (the side where the internal space 11 is located). Then, each of the projections 66 of the battery assembly 50β bites into a corresponding one of the recesses formed in the bottom walls 7 of the batteries 1 of the battery assembly 50α. Movement of the battery 1 in the storage space 61 is restricted in the battery assembly 50α by each of the protrusions 66 biting into a corresponding one of the recesses. That is, in the battery assembly 50α, the movement of the battery 1 in the directions (the first direction and the second direction) intersecting the stacking direction causes the movement of the battery assembly 50β toward the exterior portion 3 of the battery 1 of the battery assembly 50α. It is regulated by the biting of the protrusion 66 of the case bottom wall 52 . As described above, in this modification, the projection 66 formed on the case bottom wall 52 of the battery assembly 50β serves as a restricting portion that restricts movement of the batteries 1 of the battery assembly 50α.

As described above, each of the protrusions 66 is positioned at one of the four substantially rectangular corners on the outer surface of the substantially rectangular case bottom wall 52 . Therefore, even if the bottom wall 7 (exterior portion 3) of the battery 1 of the battery assembly 50α is depressed inward by pressing from the protrusion 66 of the case bottom wall 52 of the battery assembly 50β, the internal space 11 of the battery 1 of the battery assembly 50α is maintained. , the contact between the first exterior member 5 (the exterior portion 3) and the electrode group 10 is effectively prevented. Therefore, even if the bottom wall 7 (exterior portion 3) of the battery 1 of the battery assembly 50α is recessed inward by the protrusion 66 of the battery assembly 50β, the first exterior member 5 (exterior portion 3) and the electrode group 10 are formed in the battery assembly 50α. appropriate electrical isolation is ensured between

In a modification, the battery assembly 50 in which the case bottom wall 52 of the case 51 is provided with both the projecting portion 65 and the projection 66 may be used in the battery module 70 as the battery assemblies 50A to 50H. In this case, in the battery assemblies 50α and 50β stacked adjacent to each other, the protruding portion 65 of the case bottom wall 52 of the battery assembly 50β causes the battery 1 of the battery assembly 50α to rise in the same manner as in the second embodiment. movement is restricted. Movement of the batteries 1 of the battery assembly 50α is restricted by the projections 66 of the case bottom wall 52 of the battery assembly 50β in the same manner as in the example of FIG. 27 (first modification of the third embodiment). Therefore, in this modification, both the projecting portion 65 and the projection 66 formed on the case bottom wall 52 of the battery assembly 50β serve as restricting portions that restrict the movement of the batteries 1 of the battery assembly 50α.

If the case bottom wall 52 of the battery assembly 50β comes into contact with the battery 1 of the battery assembly 50α to restrict the movement of the battery 1 of the battery assembly 50α, then the projecting portion 65 and the protrusion 66 are provided. It doesn't have to be. In other words, it is sufficient that the restriction portion that restricts the movement of the batteries 1 of the battery assembly 50α is provided on the case bottom wall 52 of the battery assembly 50β.

In addition, in a second modification of the third embodiment shown in FIG. 28, the surface 75 of the lid 71 facing the side where the battery assemblies 50A to 50H are located has projections 79 similar to the projections 65 and projections. Protrusions 78 similar to 66 (four in this variant) are formed. On the surface 75, the protruding portion 65 protrudes toward the side where the battery assemblies 50A to 50H are located in the stacking direction, and each of the protrusions 78 protrudes toward the side where the battery assemblies 50A to 50H are located in the stacking direction. protrude further from In this modification, similarly to the protrusion 65 , the protrusion 79 of the lid 71 restricts movement of the battery 1 in the battery assembly 50</b>H arranged closest to the lid 71 . Similarly to the protrusion 66 , the protrusion 78 of the lid 71 restricts movement of the battery 1 in the battery assembly 50</b>H that is arranged closest to the lid 71 .

Note that, in a modification, only one of the projecting portion 79 and the projection 78 may be formed on the surface 75 of the lid 71 . Also, the configuration in which movement of the batteries 1 of the battery assembly 50H is restricted by bringing the lid 71 into contact with the batteries 1 of the battery assembly 50H may be formed by means other than the projections 79 and projections 78 described above.

Further, in a third modification of the third embodiment shown in FIG. 29, a battery assembly 50 having the same configuration as the example of FIG. 50H is used in the battery module 70 . That is, in this modification, in each of the battery assemblies 50A to 50H, the distance from the hole (first connecting portion) 57A to the inner surface of the case side wall 53A in the lateral direction is equal to or equal to the predetermined third distance α1. become almost identical. In each of the battery assemblies 50A to 50H, the distance from each of the holes (second connecting portions) 57B to the inner surface of the case side wall 53B in the horizontal direction is equal to or substantially equal to the predetermined fourth distance α2. Note that the difference between the third distance α1 and the fourth distance α2 is the same or substantially the same as the predetermined size γ described above.

Also in this modification, the battery assemblies 50α and 50β stacked adjacent to each other are arranged in the same manner as in the third embodiment. Therefore, the spring portion 35A and the terminal (first terminal) 27A of the battery assembly (first battery assembly) 50α move in the first direction (lateral direction of the battery assemblies 50α and 50β). It is located on the opposite side of the electrode group 10 to the side where the spring portion 35A and the terminal (first terminal) 27A of the battery assembly (second battery assembly) 50β are located. Therefore, the end (reference end) P1 and the terminal (second terminal) 27B of the battery 1 of the battery assembly 50β are arranged in the spring direction of the battery assembly 50α with respect to the electrode group 10 of the battery assemblies 50α and 50β in the first direction. It is located on the side where the portion 35A and the terminal (first terminal) 27A are located.

In this modification, in the battery assembly 50α, the distance from each of the holes (first connecting portions) 57A to the inner surface of the case side wall 53A in the lateral direction is the same or substantially the same as the predetermined third distance α1. In the battery assembly 50β, the distance from each of the holes (second connecting portions) 57B to the inner surface of the case side wall 53B in the lateral direction is the same or substantially the same as the predetermined fourth distance α2. Therefore, in this modified example, the inner surface of the case side wall 53A of the battery assembly (first battery assembly) 50α is aligned with the battery assembly (second battery assembly) in the first direction (lateral direction of the battery assemblies 50α and 50β). assembly) 50β with respect to the inner surface of the case side wall 53B. Then, the displacement of the inner surface of the case side wall 53A of the battery assembly 50α with respect to the inner surface of the case side wall 53B of the battery assembly 50β is the same or substantially the same as the above-mentioned predetermined amount γ. Therefore, in this modified example, unlike the third embodiment and the like, the terminal (first terminal) 27A of the battery assembly (first battery assembly) 50α is arranged in the first direction (the lateral direction of the battery assemblies 50α and 50β). direction) is not displaced or hardly displaced with respect to the terminal (second terminal) 27B of the battery assembly (second battery assembly) 50β.

In addition, in the bus bar 36 of this modified example, the contact surfaces 82A and 82B do not separate or hardly separate from each other in the direction perpendicular or substantially perpendicular to the contact surfaces 82A and 82B. That is, in the bus bar 36, the contact surfaces 82A, 82B are not displaced or hardly displaced with respect to each other in a direction perpendicular or substantially perpendicular to the contact surfaces 82A, 82B. Since the contact surfaces 82A and 82B are not separated from each other, or are hardly separated from each other, the labor involved in forming the bus bar 36 can be reduced.

As described above, in this modification, the terminal (first terminal) 27A of the battery assembly 50α is not displaced in the first direction with respect to the terminal (second terminal) 27B of the battery assembly 50β, or almost no deviation. For this reason, even if the contact surfaces 82A, 82B are not spaced from each other, or are hardly spaced apart from each other, even if a bus bar 36 is used, the bus bar to the terminal (first terminal) 27A of the battery assembly (first battery assembly) 50α 36, the contact surface (first contact surface) 82A of the bus bar 36 is in surface contact with the terminal-side contact surface 37A of the terminal 27A with no or almost no gap. In welding the bus bar 36 to the terminal (second terminal) 27B of the battery assembly (second battery assembly) 50β, the contact surface (second contact surface) 82B of the bus bar 36 contacts the terminal side of the terminal 27B. It is in surface contact with the surface 37B without gaps or almost without gaps. Thereby, similarly to the third embodiment and the like, the contact surfaces 82A of the busbars 36 are properly welded to the terminals 27A of the battery assembly 50α, and the contact surfaces 82B of the busbars 36 are properly welded to the terminals 27B of the battery assembly 50β. be.

Further, in the above-described embodiments and the like, eight battery assemblies 50A to 50H are provided in the battery module 70, but the number of battery assemblies 50 provided in the battery module 70 may be plural.

In addition, in the above-described embodiments and the like, in the battery module 70, the batteries 1 of the plurality of battery assemblies (50) are electrically connected in series, but the invention is not limited to this. In a modification, in the battery module 70, the batteries 1 of the battery assemblies (50) may be electrically connected in parallel. Also, a series connection in which the batteries 1 of the plurality of battery assemblies (50) are electrically connected in series, and a parallel connection in which the batteries 1 of the plurality of battery assemblies (50) are electrically connected in parallel. Both may be formed in battery module 70 .

In one variation, the batteries 1 of the battery assemblies 50α, 50β stacked next to each other are electrically connected in parallel. In this case, the terminal (first terminal) 27A of the battery assembly (first battery assembly) 50α is connected to the electrode group 10 of the battery assemblies 50α and 50β in the first direction (lateral direction of the battery assemblies 50α and 50β). On the other hand, it is located on the side where the terminal (first terminal) 27A of the battery assembly (second battery assembly) 50β is located. The terminal (second terminal) 27B of the battery assembly 50α is positioned with respect to the electrode group 10 of the battery assemblies 50α and 50β in the first direction. located on the side. The terminals (first terminals) 27A of the battery assemblies 50α and 50β are electrically connected to each other by the busbar 36 or the like, and the terminals (second terminals) 27B of the battery assemblies 50α and 50β are electrically connected to each other by the busbar 36 or the like. are electrically connected by

Moreover, in one or more of the plurality of battery assemblies 50, the battery module 70 of a modification may use the battery 1 having the same configuration as the example in FIG. In this case, in one or more of the plurality of battery assemblies 50, the terminals 27A, 27B project laterally on the same side relative to each other at the outer surface of the sidewalls (8A, 8B, 9A, 9B).

In a battery module (70) such as the previous embodiment, a plurality of battery assemblies (50) are provided, and each of the plurality of battery assemblies (50) is similar to any of the battery assemblies of the second embodiment and its modifications. configuration.

According to the battery of at least one of the embodiments or examples described above, the spring portion is formed from at least one of the flange and the second exterior member at the protruding portion from the opening edge of the flange and the second exterior member. . The spring portion protrudes from the side wall in the lateral direction to the side from which the first terminal protrudes or to the side opposite to the side from which the first terminal protrudes. When the spring part is elastically deformed by the action of an external force from the outside, a repulsive force having a force component in the side opposite to the side where the spring part protrudes from the side wall in the lateral direction is the reaction of the elastic force of the spring part. , acts on the first exterior member and the second exterior member. As a result, in the battery assembly housed in the case, it is possible to provide the batteries that are accurately arranged with respect to the case in the housing space.

While several embodiments of the invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and equivalents thereof.

DESCRIPTION OF SYMBOLS 1... Battery, 3... Exterior part, 5... 1st exterior member, 6... 2nd exterior member, 7... Bottom wall, 8A, 8B, 9A, 9B... Side wall, 10... Electrode group, 11... Internal space, DESCRIPTION OF SYMBOLS 12... Opening, 13... Flange, 15... Opening edge, 21... Positive electrode, 22... Negative electrode, 27A, 27B... Terminal, 30... Welding part, 35A, 35B... Spring part, 36... Bus bar, 41A, 41B... Bending part, 42A, 42B end face 50, 50A to 50H battery assembly 51 case 52 case bottom wall 53A, 53B, 55A, 55B case side wall 57A, 57B hole (connecting portion) 61 storage space , 62...Case opening, 65...Protrusion, 66...Protrusion, 70...Battery module, 82A, 82B...Contact surface.

Claims (15)

A first exterior member comprising a bottom wall and side walls defining an interior space and formed of metal, wherein an opening of the interior space is formed on the side opposite to the bottom wall, and an opening of the opening a first facing member comprising a flange projecting outwardly from an edge relative to the side wall;
an electrode group that includes a positive electrode and a negative electrode and is accommodated in the internal space;
a second exterior member made of metal and arranged to face the flange while closing the opening of the internal space;
a welding portion where the flange and the second exterior member are welded at a projecting portion outward from the opening edge of the flange and the second exterior member;
Attached as a pair of electrode terminals to the outer surface of the side wall of the first exterior member, and protruding on the outer surface of the side wall on the same side or opposite sides in the lateral direction a first terminal and a second terminal for
The projecting portion from the opening edge of the flange and the second exterior member is formed from at least one of the flange and the second exterior member, and the first terminal protrudes in the lateral direction. or the side opposite to the side from which the first terminal protrudes, the spring portion protruding from the side wall, and is elastically deformed by the action of an external force from the outside, thereby A spring portion that causes a repulsive force having a force component to a side opposite to the side where the spring portion protrudes from the side wall to act on the first exterior member and the second exterior member as a reaction to elastic force. and,
A battery comprising: 2. The battery according to claim 1, wherein said welded portion is provided between said opening edge and said spring portion at said projecting portion of said flange and said second exterior member from said opening edge. The second exterior member protrudes outward from an outer edge of the flange,
The spring portion is formed from a portion of the second exterior member that protrudes outward from the outer edge of the flange,
3. The battery of claim 2. 4. The battery according to any one of claims 1 to 3, wherein said spring portion is provided at a position apart from said first terminal and said second terminal in the circumferential direction of said opening. At the projecting portion of the flange and the second exterior member from the opening edge, at least one of the flange and the second exterior member is bent, and the side opposite to the side where the spring portion protrudes in the lateral direction. further comprising a bent portion protruding toward the side wall with respect to the side wall,
The bent portion has an end surface forming an end opposite to the side where the spring portion protrudes in the horizontal direction,
5. The battery of any one of claims 1-4. The side wall includes a first side wall extending along a vertical direction intersecting the horizontal direction, and a first side wall extending along the vertical direction, and the side wall extending along the horizontal direction with the internal space interposed therebetween. a second sidewall facing the first sidewall;
the first terminal attached to the outer surface of the first sidewall;
the second terminal is attached to the outer surface of the first sidewall or the outer surface of the second sidewall;
6. The battery of any one of claims 1-5. The spring portion protrudes from the side wall to one side in a vertical direction that intersects the horizontal direction, and is elastically deformed by the action of an external force, thereby extending the spring portion in the vertical direction. 6. A repulsive force having a force component directed to a side opposite to the side protruding from said side wall is applied to said first exterior member and said second exterior member as a reaction to elastic force. The battery of any one of Claims 1 to 3. With respect to the horizontal direction, a predetermined first distance is provided from the end opposite to the side where the spring portion protrudes to the first terminal,
With respect to the lateral direction, a predetermined second distance is provided from the end opposite to the side where the spring portion protrudes to the second terminal,
8. The battery of any one of claims 1-7. A battery according to any one of claims 1 to 7;
A case comprising a case bottom wall and a case side wall defining a storage space, wherein a case opening is formed as an opening of the storage space on the opposite side of the case bottom wall, wherein the battery is stored in the storage space. a case;
and
In the storage space, as the reaction to the elastic force of the spring portion, a repulsive force from the side wall of the case acts on the battery,
In the storage space, the battery contacts the side wall of the case at a reference end, which is the end opposite to the side where the spring portion protrudes in the horizontal direction, due to the repulsive force.
battery assembly. the first terminal and the second terminal of the battery protrude in opposite directions to each other in the lateral direction;
the spring portion of the battery protrudes from the side wall in the lateral direction on the side where the first terminal protrudes;
With respect to the lateral direction, a predetermined first distance is provided from a contact position of the reference end of the battery to the side wall of the case to the first terminal,
With respect to the lateral direction, a predetermined second distance is provided from the contact position of the reference end of the battery to the case side wall to the second terminal,
The case side wall is
A first connecting portion provided on a side of the electrode group on which the first terminal and the spring portion are positioned in the lateral direction and serving as a connecting position to another battery assembly, a first connecting portion disposed outwardly with respect to the inner surface of the case side wall;
a second connecting portion provided on a side of the electrode group on which the second terminal and the reference end are positioned with respect to the lateral direction, and serving as a connecting position to another battery assembly; a second connecting portion disposed outwardly with respect to the inner surface of the case sidewall for
with
a predetermined third distance in the lateral direction from the first connecting portion to the inner surface of the case side wall;
a predetermined fourth distance in the lateral direction from the second connecting portion to the inner surface of the case side wall;
the difference of the third distance to the fourth distance is of a predetermined magnitude based on the first distance and the second distance;
10. The battery assembly of claim 9. A battery module comprising a plurality of battery assemblies according to claim 9 . 12. The battery module of claim 11, wherein the plurality of battery assemblies are stacked such that the lateral direction of the batteries intersects the stacking direction. the plurality of battery assemblies includes a first battery assembly and a second battery assembly stacked next to each other;
in each of the first battery assembly and the second battery assembly, the first terminal and the second terminal of the battery protrude in opposite directions to each other in the lateral direction;
In each of the first battery assembly and the second battery assembly, the spring portion of the battery protrudes from the side wall in the lateral direction on the side where the first terminal protrudes,
The first terminal and the spring portion of the first battery assembly are arranged in the lateral direction with respect to the electrode group of the first battery assembly and the second battery assembly. located on the side opposite to the side on which the first terminal and the spring portion are located,
13. The battery module of claim 12. further comprising a connecting member electrically connecting between the first terminal of the first battery assembly and the second terminal of the second battery assembly;
In each of the first battery assembly and the second battery assembly,
With respect to the lateral direction of the battery, a predetermined first distance is provided from a contact position of the reference end of the battery to the side wall of the case to the first terminal of the battery,
With respect to the lateral direction of the battery, a predetermined second distance is provided from the contact position of the reference end of the battery to the side wall of the case to the second terminal of the battery,
the first terminal of the first battery assembly is offset in the lateral direction with respect to the second terminal of the second battery assembly;
the displacement of the first terminal of the first battery assembly relative to the second terminal of the second battery assembly is a predetermined amount based on the first distance and the second distance;
The connection member is
a first contact surface contacting the first terminal of the first battery assembly;
a second contact surface in contact with the second terminal of the second battery assembly and parallel to the first contact surface;
with
In the connection member, in a direction perpendicular to the first contact surface and the second contact surface, the first contact surface is shifted from the second contact surface by the predetermined deviation that is the same as the deviation. located a size apart
14. The battery module of claim 13. the plurality of battery assemblies includes a first battery assembly and a second battery assembly stacked next to each other;
the case bottom wall of the case of the second battery assembly faces the battery of the first battery assembly through the case opening of the first battery assembly ;
The case bottom wall of the case of the second battery assembly includes a restricting portion that interferes with the batteries of the first battery assembly and restricts movement of the batteries in the first battery assembly,
13. The battery module of claim 12.

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