KR20230160355A - battery - Google Patents

Abstract

The battery of the embodiment includes an external container, a cover member, an electrode group, an electrode terminal, and a lead. In the electrode group stored in the internal cavity of the external container, a current collection tab protrudes outward in the horizontal direction, and a lead electrically connects the current collection tab to the electrode terminal. In the lead, the electrode terminal is connected to the top plate portion disposed between the cover member and the electrode group, and the leg plate portion bent with respect to the top plate portion is joined to the current collection tab. In the ceiling plate portion, a concave portion is formed on the lower surface of the ceiling plate opposite to the electrode group on the side opposite to the side where the electrode group is located. The concave portion extends beyond the connection position of the electrode terminal and continues outward in the horizontal direction from the inner edge surface of the ceiling plate forming the inner end of the ceiling plate portion.

Description

battery

Embodiments of the present invention relate to batteries.

With the advancement of electronic devices such as mobile phones and personal computers, batteries such as secondary batteries used in these electronic devices are required to be smaller and lighter. A secondary battery that realizes miniaturization and weight reduction and has a high energy density includes a lithium ion secondary battery. Meanwhile, secondary batteries such as lead acid batteries and nickel metal hydride batteries are used as large-sized and high-capacity power sources mounted on vehicles such as electric vehicles, hybrid vehicles, electric bikes, and forklifts. Additionally, in recent years, lithium-ion secondary batteries with high energy density have been developed for adoption as large-sized and high-capacity power sources mounted on vehicles. In the development of lithium ion secondary batteries to be mounted on vehicles, it is required to realize a longer battery life and improved safety, as well as to increase the size and capacity of the battery.

There are batteries such as lithium ion secondary batteries in which an electrode group is stored in an internal cavity of an external container. In this battery, the external container has a bottom wall and a peripheral wall, and the internal cavity of the external container opens on the side opposite to the bottom wall with respect to the height direction. Then, a cover member is installed on the peripheral wall of the external container, and the opening of the internal cavity is closed by the cover member. Additionally, in the battery, the electrode terminal is exposed to the outside and is disposed on the outer surface of the cover member. And, in the internal cavity, a current collection tab protrudes from the electrode group to the outside in the horizontal direction intersecting the height direction. Then, the lead electrically connects the current collection tab of the electrode group and the electrode terminal.

In the above-mentioned battery, it is required to increase the capacity of the battery by increasing the volume of the electrode group, such as by increasing the space occupied by the electrode group in the internal cavity. In addition, it is required to increase the capacity of the battery without increasing the electrical resistance in the electrical path between the electrode group and the electrode terminal, such as by increasing the volume of the electrode group without reducing the cross-sectional area of the lead.

Japanese Patent Publication No. 2014-7036 Japanese Patent Publication No. 2006-93122

The problem to be solved by the present invention is to provide a battery whose capacity can be increased without increasing the electrical resistance in the electrical path between the electrode group and the electrode terminal.

According to the embodiment, the battery includes an external container, a cover member, an electrode group, an electrode terminal, and a lead. The external container has a bottom wall and a peripheral wall, and an internal cavity is formed in the external container that opens on a side opposite to the side where the bottom wall is located with respect to the height direction. The cover member is installed on the peripheral wall of the external container with the opening of the internal cavity blocked. The electrode group has current collection tabs that protrude outward in the horizontal direction crossing the height direction, and is stored in the internal cavity of the external container. The electrode terminal is exposed to the outside on the outer surface of the cover member, and the lead electrically connects the current collection tab of the electrode group and the electrode terminal. The lid has a top plate portion and a leg plate portion. The top plate portion is disposed between the cover member and the electrode group in the internal cavity, and electrode terminals are connected to the top plate portion. The leg plate portion is bent relative to the top plate portion toward the side where the bottom wall is located, and is joined to the current collection tab. The ceiling plate portion includes an inner edge surface of the ceiling plate that forms an inner end of the ceiling plate portion in the horizontal direction, a lower surface of the ceiling plate that faces the electrode group, and a concave portion that is concave in the lower surface of the ceiling plate on the opposite side from the side where the electrode group is located. The concave portion extends beyond the connection position of the electrode terminal to the top plate portion and is formed continuously from the inner edge surface of the top plate toward the outer side in the horizontal direction.

Figure 1 is a perspective view showing the battery according to the first embodiment disassembled by member.
Figure 2 is a perspective view showing a battery according to the first embodiment.
Figure 3 is a perspective view schematically showing the lead configuration of a battery according to the first embodiment.
FIG. 4 is a cross-sectional view schematically showing a cross-section passing through a position spaced inward in the horizontal direction with respect to the through hole of the lead and perpendicular or substantially perpendicular to the horizontal direction in the battery according to the first embodiment.
FIG. 5 is a cross-sectional view schematically showing a cross-section passing through a lead through-hole and perpendicular or substantially perpendicular to the horizontal direction in the battery according to the first embodiment.
Figure 6 is a perspective view schematically showing the lead configuration of a battery according to the first modification example.
Figure 7 is a perspective view schematically showing the lead configuration of a battery according to a second modification.

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

(First Embodiment)

1 and 2 show a battery 1 according to the first embodiment. As shown in FIGS. 1 and 2, the battery 1 includes an electrode group 2, an external container 3, and a cover member 5. The exterior container 3 and the lid member 5 are each formed of metal such as aluminum, aluminum alloy, iron, copper, or stainless steel. Here, in the battery 1 (external container 3), the depth direction (direction indicated by arrows direction indicated), and a height direction (direction indicated by arrow Z1 and arrow Z2) that intersects (orthogonal or approximately perpendicular to) both the depth direction and the horizontal direction are defined. In each of the battery 1 and the external container 3, the dimension in the depth direction is smaller than the dimensions in the horizontal direction and the dimensions in the height direction. In addition, Figure 1 is a perspective view showing the components disassembled by member, and Figure 2 is a perspective view.

The external container (3) has a bottom wall (6) and a peripheral wall (7). The internal cavity 8 in which the electrode group 2 is housed is defined by the bottom wall 6 and the peripheral wall 7. In the external container 3, the internal cavity 8 opens toward the side opposite to the side on which the bottom wall 6 is located in the height direction. The peripheral wall 7 has two pairs of side walls 11 and 12. A pair of side walls 11 face each other in the horizontal direction with an internal cavity 8 therebetween. A pair of side walls 12 face each other in the depth direction with an internal cavity 8 therebetween. Each of the side walls 11 extends continuously along the depth direction between the side walls 12. Each of the side walls 12 extends continuously along the horizontal direction between the side walls 11. The cover member 5 is installed on the peripheral wall 7 at an end opposite to the bottom wall 6. For this reason, the lid member 5 closes the opening of the internal cavity 8 of the outer container 3. The cover member 5 and the bottom wall 6 face each other in the height direction with an internal cavity 8 therebetween.

The electrode group 2 includes a negative electrode 13A and a positive electrode 13B. In the electrode group 2, a separator (not shown) is interposed between the negative electrode 13A and the positive electrode 13B. The separator is made of an electrically insulating material and electrically insulates the negative electrode 13A from the positive electrode 13B.

The negative electrode 13A includes a negative electrode current collector such as negative electrode current collector foil, and a negative electrode active material-containing layer (not shown) supported on the surface of the negative electrode current collector. The negative electrode current collector is not limited to these, but is, for example, aluminum foil, aluminum alloy foil, or copper foil, and has a thickness of about 10 μm to 20 μm. The negative electrode active material-containing layer includes a negative electrode active material and may optionally contain a binder and a conductive agent. The negative electrode active material is not particularly limited, but includes metal oxides, metal sulfides, metal nitrides, and carbon materials that can occlude and release lithium ions. The negative electrode current collector includes a negative electrode current collection tab 15A with the negative electrode active material-containing layer as the unsupported portion.

The positive electrode 13B includes a positive electrode current collector such as positive electrode current collector foil, and a positive electrode active material-containing layer (not shown) supported on the surface of the positive electrode current collector. The positive electrode current collector is not limited to these, but is, for example, aluminum foil or aluminum alloy foil, and has a thickness of about 10 μm to 20 μm. The positive electrode active material-containing layer includes a positive electrode active material and may optionally include a binder and a conductive agent. Examples of the positive electrode active material include, but are not limited to, oxides, sulfides, and polymers that can occlude and release lithium ions. The positive electrode current collector includes a positive electrode current collection tab 15B with the positive electrode active material-containing layer as the unsupported portion.

In an example of the electrode group 2 shown in FIG. 1 or the like, the negative electrode 13A, the positive electrode 13B, and the separator are wound around the winding axis W, with the separator sandwiched between the negative electrode active material-containing layer and the positive electrode active material-containing layer. do. In another example, the electrode group 2 has a stack structure in which a plurality of negative electrodes 13A and a plurality of positive electrodes 13B are alternately stacked, and a separator is provided between the negative electrode 13A and the positive electrode 13B. . In the electrode group 2, the negative electrode current collection tab 15A protrudes relative to the positive electrode 13B and the separator. And, the positive electrode current collection tab 15B protrudes in a direction opposite to the protrusion direction of the negative electrode current collection tab 15A with respect to the negative electrode 13A and the separator. In an example such as that shown in FIG. 1, the pair of current collection tabs 15 (negative electrode current collection tab 15A and positive electrode current collection tab 15B) are oriented in an axial direction along the winding axis W (direction indicated by arrows Y3 and Y4). For , they protrude on opposite sides with respect to each other.

Additionally, in the electrode group 2, the negative electrode current collection tab 15A protrudes with respect to the negative electrode active material-containing layer, and the positive electrode current collection tab 15B is on the side opposite to the side on which the negative electrode current collection tab 15A protrudes with respect to the positive electrode active material-containing layer. protrudes into For this reason, the boundary position Ba between the negative electrode current collection tab 15A (the portion not carrying the negative electrode active material-containing layer) and the negative electrode active material-containing layer becomes the root position of the protruding portion of the negative electrode current collection tab 15A with respect to the negative electrode active material-containing layer. This is the end (coated end) of the active material-containing layer on the side where the negative electrode current collection tab 15A is located. And, the boundary position Bb between the positive electrode current collection tab 15B (the portion not carrying the positive electrode active material-containing layer) and the positive electrode active material-containing layer becomes the root position of the protruding portion of the positive electrode current collection tab 15B with respect to the positive electrode active material-containing layer, and This is the end (coated end) of the containing layer on the side where the positive electrode current collection tab 15B is located. Additionally, in the area between the boundary positions Ba and Bb in the axial direction along the winding axis W (the protruding direction of the pair of current collection tabs 15), the negative electrode active material-containing layer is supported on the surface of the negative electrode current collector (coated). ), and a positive electrode active material-containing layer is supported (coated) on the surface of the positive electrode current collector.

In the electrode group 2, the width direction (direction indicated by arrows Z3 and Z4) intersects (orthogonal or approximately perpendicular to) the protruding direction of the current collection tab 15 (axial direction of the winding axis W) and collects current. Thickness directions (directions indicated by arrows And, in the electrode group 2, the dimension in the thickness direction is smaller than each of the dimensions in the axial direction and the dimension in the width direction. For this reason, the electrode group 2 is formed in a flat shape. Additionally, in each of the pair of current collection tabs 15, a plurality of strip-shaped portions are bundled.

In this embodiment, the width direction of the electrode group 2 coincides with or approximately coincides with the height direction of the battery 1, and the thickness direction coincides with or approximately coincides with the depth direction of the battery 1, so that the internal cavity It is placed in (8). 1 and other examples, the electrode group 2 is disposed in the internal cavity 8 with the winding axis W along the horizontal direction of the battery 1. Each of the pair of current collection tabs 15 protrudes outward in the horizontal direction of the battery 1 in the electrode group 2. The negative electrode current collection tab 15A protrudes from the positive electrode 13B and the separator on one side in the horizontal direction of the battery 1, and protrudes from the boundary position Ba with the negative electrode active material-containing layer on one side in the horizontal direction. In addition, the positive electrode current collection tab 15B protrudes on the side opposite to the side on which the negative electrode current collection tab 15A protrudes with respect to the negative electrode 13A and the separator in the horizontal direction of the battery 1, and forms a boundary with the positive electrode active material-containing layer. It protrudes from position Bb to the other side in the horizontal direction.

In addition, in examples such as those shown in FIG. 1, the electrode group 2 is wound around the winding axis W along the transverse direction of the battery 1, as described above. For this reason, in the electrode group 2, a curved surface 14 is formed on the outer surface of one end in the width direction. In the battery 1, the curved surface 14 forms an end portion of the electrode group 2 on the side where the cover member 5 is located, and the curved surface 14 forms an end portion of the electrode group 2 on the side where the cover member 5 is located. It becomes the end face. That is, in the electrode group 2, the curved surface 14 is formed by the outer surface of the end on the side where the cover member 5 is located. The curved surface 14 is formed in a portion of the electrode group 2 different from the current collection tabs 15 (15A, 15B), for example, between boundary positions Ba and Bb in the horizontal direction of the battery 1. is formed In a cross section perpendicular or substantially perpendicular to the transverse direction of the battery 1 (axial direction of the electrode group 2), the curved surface 14 has an arc shape.

Additionally, in the internal cavity 8, the electrode group 2 is held (impregnated) with an electrolyte solution (not shown). The electrolyte solution may be a non-aqueous electrolyte solution obtained by dissolving an electrolyte in an organic solvent, or may be an aqueous electrolyte solution such as an aqueous solution. Instead of the electrolyte solution, a gel electrolyte may be used, or a solid electrolyte may be used. When a solid electrolyte is used as the electrolyte, in the electrode group, the solid electrolyte is interposed between the negative electrode 13A and the positive electrode 13B instead of the separator. In this case, the negative electrode 13A is electrically insulated from the positive electrode 13B by the solid electrolyte.

In the battery 1, a pair of electrode terminals 16 are provided on the cover member 5. The electrode terminal 16 is formed of a conductive material such as metal. One side of the electrode terminal 16 is the negative electrode terminal 16A of the battery 1, and the other side of the pair of electrode terminals 16 from the negative electrode terminal 16A is the positive electrode terminal 16B of the battery 1. Each of the electrode terminals 16 is disposed on the outer surface of the cover member 5 in a state exposed to the outside of the battery 1. A pair of electrode terminals 16 are arranged to be spaced apart from each other in the horizontal direction of the battery 1.

Additionally, the cover member 5 is provided with a pair of through holes 17. Each of the through holes 17 penetrates the cover member 5 along the height direction of the battery 1. On the outer surface of the cover member 5, an insulating member 18 is provided between each of the electrode terminals 16 and the cover member 5. Additionally, an insulating gasket 19 is disposed in each of the through holes 17. Each of the electrode terminals 16 is electrically insulated from the cover member 5 and the external container 3 by the insulating member 18 and the insulating gasket 19.

A pair of leads 20 is disposed in the internal cavity 8 of the external container 3. One side of the pair of leads 20 is the negative electrode side lead 20A, and the other side of the pair of leads 20 from the negative electrode side lead 20A is the positive electrode side lead 20B. The negative electrode side lead 20A forms at least a portion of the electrical path between the negative electrode current collection tab 15A and the negative electrode terminal 16A. For this reason, the negative electrode side lead 20A electrically connects the negative electrode current collection tab 15A and the negative electrode terminal 16A of the electrode group 2. Additionally, the positive electrode side lead 20B forms at least a portion of the electrical path between the positive electrode current collection tab 15B and the positive electrode terminal 16B. For this reason, the positive electrode side lead 20B electrically connects the positive electrode current collection tab 15B of the electrode group 2 and the positive electrode terminal 16B. Each lead 20 is formed of a conductive material such as metal. Conductive materials forming the lead 20 include aluminum, stainless steel, copper, and iron.

Additionally, a pair of insulating guards 21 and a pair of insulating tapes 22 are disposed in the internal cavity 8 of the external container 3. Each of the insulating guard 21 and the insulating tape 22 is formed of a material having electrical insulation properties. The insulation guard 21A, which is one side of the insulation guard 21, is disposed between the negative electrode side lead 20A (negative electrode current collection tab 15A) and the peripheral wall 7 of the external container 3. Each of the negative electrode side lead 20A and the negative electrode current collection tab 15A is prevented from contacting the external container 3 by the insulating guard 21A and is electrically insulated from the external container 3. The insulation guard 21B, which is on the other side from the insulation guard 21A of the insulation guard 21, is located between the positive electrode side lead 20B (positive electrode current collection tab 15B) and the peripheral wall 7 of the external container 3. It is placed. Each of the positive electrode side lead 20B and the positive electrode current collection tab 15B is prevented from contacting the external container 3 by the insulating guard 21B and is electrically insulated from the external container 3. Each of the insulating guards 21 is fixed to the electrode group 2 by a corresponding side of the insulating tape 22 .

Additionally, the electrode group pressing member 23 is disposed between the electrode group 2 and the cover member 5 with respect to the height direction of the battery 1. The electrode group pressing member (internal insulating member) 23 is formed of a material having electrical insulation properties. The pair of current collection tabs 15 and the pair of leads 20 are prevented from contacting the cover member 5 by the electrode group pressing member 23 and are electrically insulated from the cover member 5. Additionally, the electrode group pressing member 23 is provided with a pair of through holes 25. Each of the through holes 25 penetrates the electrode group pressing member 23 along the height direction of the battery 1.

In addition, in the example of FIGS. 1 and 2, a gas opening valve 26 and a liquid injection port 27 are formed in the cover member 5. Then, a sealing plate 28 that blocks the liquid injection port 27 is welded to the outer surface of the cover member 5. The gas release valve 26 and the liquid injection port 27 are disposed between a pair of electrode terminals 16 in the horizontal direction of the battery 1. Additionally, in one example, the gas release valve 26 and the liquid injection port 27 do not need to be provided in the battery 1.

Figure 3 shows the configuration of the lid 20. In examples such as FIGS. 1 and 3, each of the pair of leads 20 (20A, 20B) is provided with a top plate portion 31 and a pair of leg plate portions 32 and 33. In each top plate portion 31 of the lead 20, the plate longitudinal direction (direction indicated by arrows Y5 and Y6) and the plate width direction (arrows (direction indicated by ), and the sheet thickness direction (direction indicated by arrow Z5 and arrow Z6) that intersects (orthogonal or approximately perpendicular to) both the sheet longitudinal direction and the sheet width direction are defined. Each top plate portion 31 of the lid 20 has edge surfaces E1 to E4. In each of the top plate portions 31, an end on one side of the plate longitudinal direction is formed by the edge surface E1, and an end on the opposite side to the edge surface E1 is formed by the edge surface E2. do. In addition, in each of the top plate portions 31, an end on one side of the plate width direction is formed by the edge surface E3, and an end on the opposite side to the edge surface E3 is formed by the edge surface E4. do. In each of the leads 20, each of the edge surfaces E1 and E2 extends along the board width direction between the edge surfaces E3 and E4, and each of the edge surfaces E3 and E4 has an edge surface E1. , E2) is installed extending along the longitudinal direction of the plate.

Accordingly, in each of the lids 20, the top plate portion 31 extends continuously along the plate longitudinal direction from the edge surface E1 to the edge surface E2, and from the edge surface E3 to the edge surface E4. It is installed continuously extending along the direction of the plate width. Additionally, each of the ceiling plate portions 31 is provided with a ceiling plate lower surface 35 and a ceiling plate upper surface 36. In each of the ceiling plate portions 31, the ceiling plate lower surface 35 faces one side in the plate thickness direction, and the ceiling plate upper surface 36 faces the opposite side from the ceiling plate lower surface 35 in the plate thickness direction. In each lid 20, the dimension between the lower surface 35 of the ceiling plate and the upper surface 36 of the ceiling plate is defined as the plate thickness of the ceiling plate portion 31. Additionally, in each of the leads 20, a through hole 37 is formed that penetrates the ceiling plate portion 31 along the plate thickness direction from the top surface 36 of the ceiling plate to the bottom surface 35 of the ceiling plate.

In each of the lids 20, each of the pair of leg plate portions 32 and 33 is located at a position opposite to the edge surface E1 with respect to the through hole 37 with respect to the longitudinal direction of the top plate portion 31, that is, , It is connected to the top plate portion 31 between the through hole 37 and the edge surface E2 with respect to the longitudinal direction of the top plate portion 31. In examples such as FIGS. 1 and 3, the leg plate portion 32 is connected to the end of the top plate portion 31 of each lid 20 on the side where the edge surface E2 of the edge surface E3 is located. The leg plate portion 33 is connected to the end of the edge surface E4 on the side where the edge surface E2 is located. In each of the lids 20, each of the leg plate portions 32 and 33 is bent with respect to the top plate portion 31 on one side of the plate thickness direction of the top plate portion 31, that is, on the side toward which the ceiling plate lower surface 35 faces. do. In examples such as FIGS. 1 and 3, in each of the lids 20, the bending line at the bending position of the top plate 31 of each of the leg plate portions 32 and 33 is in the longitudinal direction of the top plate portion 31. Follow.

In each of the lids 20, each of the leg plate portions 32 and 33 is installed extending from a connection position to the top plate portion 31 (a bending position with respect to the ceiling plate portion 31) toward the side toward which the ceiling plate lower surface 35 faces. , the leg plate portions 32 and 33 are arranged to be spaced apart from each other in the width direction of the ceiling plate portion 31. In each of the leads 20, with respect to each of the leg plate portions 32 and 33, there is a plate longitudinal direction, a plate width direction that intersects (or is perpendicular to or approximately perpendicular to) the plate longitudinal direction, and both the plate longitudinal direction and the plate width direction. The sheet thickness direction intersecting (orthogonal or approximately perpendicular to) is defined. In examples such as FIGS. 1 and 3, in each of the leads 20, the plate length direction of each of the leg plate portions 32 and 33 coincides with or approximately coincides with the plate thickness direction of the top plate portion 31, and the leg plate portion ( 32, 33) The width direction of each plate coincides with or approximately coincides with the plate length direction of the ceiling plate portion 31, and the plate thickness direction of each leg plate portion 32, 33 coincides with the plate width direction of the ceiling plate portion 31. Or roughly the same.

In each of the leads 20, the plate thickness direction of the top plate portion 31 coincides with or approximately coincides with the height direction of the battery 1, and the plate width direction of the top plate portion 31 corresponds to the depth direction of the battery 1. It is placed in the internal cavity 8 in a coincident or approximately coincident state. Additionally, in the internal cavity 8, the top plate portion 31 of each lead 20 is disposed between the cover member 5 and the electrode group 2 in the height direction of the battery 1, and the battery ( It is disposed between the electrode group pressing member 23 and the electrode group 2 in the height direction of 1). Accordingly, the electrode group pressing member 23 is disposed between the top plate portion 31 of each lead 20 and the cover member 5. Additionally, in each of the leads 20 disposed in the internal cavity 8, the edge surface E2 of the top plate portion 30 is disposed on the outer side of the battery 1 in the horizontal direction with respect to the edge surface E1. Accordingly, in each of the leads 20, the edge surface E1 is the inner edge surface of the top plate forming the inner end of the top plate portion 31 with respect to the horizontal direction of the battery 1, and the edge surface E2 is the edge surface of the battery ( It becomes the outer edge surface of the ceiling plate that forms the outer end of the ceiling plate portion 31 in the horizontal direction of 1). Therefore, in the internal cavity 8, each of the ceiling plate portions 31 extends outward in the horizontal direction from the edge surface (ceiling plate inner edge surface) E1 to the edge surface (ceiling plate outer edge surface) E2. do.

In addition, in each of the leads 20 disposed in the internal cavity 8, the top plate lower surface 35 of the top plate portion 31 faces the side where the electrode group 2 is located with respect to the height direction of the battery 1, It faces the electrode group (2). In each of the leads 20, the top plate lower surface 35 of the top plate portion 31 faces the electrode group 2 from the side where the cover member 5 is located. In addition, in each of the leads 20, the top surface 36 faces the side where the cover member 5 is located with respect to the height direction of the battery 1, and with the electrode group pressing member 23 sandwiched therebetween, It faces the cover member (5). Additionally, each of the leads 20 is connected to a corresponding electrode terminal 16 through the through hole 37 . Accordingly, in each of the leads 20, the through hole 37 serves as a connection position on one corresponding side of the electrode terminal 16. Each of the pair of electrode terminals 16 is sequentially inserted into the corresponding side of the through hole 17, the corresponding side of the through hole 25, and the corresponding side of the through hole 37. Then, each of the electrode terminals 16 is connected to the corresponding top plate portion 31 on one side of the lead 20 by caulking or the like. In addition, in each of the electrode terminals 16, the portion caulked by caulking (plastically deformed portion) is joined to the lower surface 35 of the top plate 35 of the corresponding top plate portion 31 of the lead 20 by ultrasonic welding or the like. do.

In addition, in each of the leads 20 disposed in the internal cavity 8, a pair of leg plate portions 32 and 33 are connected to the through hole 37 (connection position of the electrode terminal 16) of the battery 1. Located on the outer side in the horizontal direction, each of the leg plate portions 32 and 33 is connected to the top plate portion 31 at a position outside the connection position of the electrode terminal 16 in the horizontal direction of the battery 1. In each of the leads 20, a pair of leg plate portions 32 and 33 are arranged to be spaced apart from each other in the depth direction of the battery 1. In each of the leads 20, each of the leg plate portions 32 and 33 extends along the height direction of the battery 1 from a connection position to the top plate portion 31 (a bending position with respect to the top plate portion 31), It bends toward the side where the bottom wall (6) is located with respect to the ceiling plate portion (31). In examples such as FIGS. 1 and 3, in each of the lids 20, the bending line at the bending position with respect to the top plate 31 of each of the leg plates 32 and 33 follows the horizontal direction of the battery 1. .

In addition, in each of the lids 20, the leg plate portion 32 has a pair of leg main surfaces 41 and 42, and the leg plate portion 33 has a pair of leg main surfaces 43 and 44. In each leg plate portion 32 of the lid 20, the main surface of the leg 41 faces the inside of the battery 1 in the depth direction and faces one side of the leg plate portion 32 in the plate thickness direction. In addition, in each leg plate portion 32 of the lid 20, the leg main surface 42 is on the opposite side from the leg main surface 41 with respect to the depth direction of the battery 1 (plate thickness direction of the leg plate portion 32). It faces outward in the depth direction of the battery 1. In each of the leads 20, at the connection position of the leg plate portion 32 to the top plate portion 31, the leg main surface 41 is connected to the top plate lower surface 35, and the leg main surface 42 is connected to the top plate upper surface 36. is connected to In addition, in each leg plate portion 33 of the lid 20, the main surface of the leg 43 faces the inside of the battery 1 in the depth direction and faces one side of the leg plate portion 33 in the plate thickness direction. In addition, in each leg plate portion 33 of the lid 20, the leg main surface 44 is on the opposite side from the leg main surface 43 with respect to the depth direction of the battery 1 (plate thickness direction of the leg plate portion 33). It faces outward in the depth direction of the battery 1. In each of the leads 20, at the connection position of the leg plate portion 33 to the top plate portion 31, the leg main surface 43 is connected to the top plate lower surface 35, and the leg main surface 44 is connected to the top plate upper surface 36. is connected to

Therefore, in each of the lids 20, the leg main surfaces 42 of the leg plate portion 32 and the leg main surfaces 44 of the leg plate portion 33 each have a peripheral wall 7 (corresponding one side of the side wall 12). It faces the side where it is located, and faces the outer peripheral side of the internal cavity 8. In addition, in each of the leads 20, the leg main surface 41 of the leg plate portion 32 and the leg main surface 43 of the leg plate portion 33 each face the inner peripheral side of the internal cavity 8, and the electrode group 2 ) faces the side where it is located. And, in each of the leads 20, the leg main surfaces 41 and 43 face each other with the corresponding one side of the pair of current collection tabs 15 sandwiched between them. In each of the leads 20, the dimension between the leg main surfaces 41 and 42 is defined as the plate thickness of the leg plate portion 32, and the dimension between the leg main surfaces 43 and 44 is defined as the plate thickness of the leg plate portion 33. It is defined as thickness.

In addition, in each of the lids 20, the leg plate portion 32 has edge surfaces (leg edge surfaces) E5 and E6, and the leg plate portion 33 has edge surfaces (leg edge surfaces) E7 and E8. Equipped with In each of the leg plate portions 32, an edge on one side of the leg plate portion 32 in the width direction is formed by the edge surface E5, and an inner end of the leg plate portion 32 is formed with respect to the transverse direction of the battery 1. is formed. In addition, in each of the leg plate portions 32, an edge surface E6 forms an end opposite to the edge surface E5 with respect to the transverse direction of the battery 1 (the width direction of the leg plate portion 32). And, the outer end of the leg plate portion 32 is formed with respect to the horizontal direction of the battery 1. For this reason, in each of the lids 20, each of the leg main surfaces 41 and 42 extends outward in the horizontal direction from the edge surface E5 to the edge surface E6, and the leg plate portion 32 extends from the edge surface E5 to the edge surface E6. It is installed extending outward in the horizontal direction from (E5) to the edge surface (E6).

In addition, in each of the leg plate portions 33, an end on one side in the width direction of the leg plate portion 33 is formed by the edge surface E7, and the leg plate portion 33 is formed with respect to the transverse direction of the battery 1. An inner end is formed. In addition, in each of the leg plate portions 33, an edge surface E8 forms an end opposite to the edge surface E7 with respect to the transverse direction of the battery 1 (the width direction of the leg plate portion 33). And the outer end of the leg plate portion 33 is formed with respect to the horizontal direction of the battery 1. For this reason, in each of the lids 20, each of the leg main surfaces 43 and 44 extends outward in the horizontal direction from the edge surface E7 to the edge surface E8, and the leg plate portion 33 extends from the edge surface E7 to the edge surface E8. It is installed extending outward in the horizontal direction from (E7) to the edge surface (E8).

In an example such as Figure 1, in each of the current collection tabs 15, binding portions where a plurality of strip-shaped portions are tied are formed at two locations. Additionally, two pairs of backup leads 46 and 47 are disposed in the internal cavity 8. Each of the backup leads 46 and 47 is made of a conductive material such as metal. In each of the current collection tabs 15, one side of the two binding portions is sandwiched by a corresponding side of the pair of backup leads 46. And, in each of the current collection tabs 15, one side of the two binding portions is placed on the main surface of the leg plate portion 32 of the corresponding side of the lead 20 with the corresponding side of the backup lead 46 in between ( 41). Additionally, in each of the current collection tabs 15, the other side of the two binding portions is sandwiched by the corresponding side of the pair of backup leads 47. And, in each of the current collection tabs 15, the other side of the two binding portions is on the main surface of the leg plate portion 33 of the corresponding side of the lead 20 with the corresponding side of the backup lead 47 interposed therebetween. It is conjugated to (43).

In addition, in each of the current collection tabs 15, one side of the two binding portions is joined to the corresponding one leg plate portion 32 of the lead 20 by, for example, ultrasonic welding, and the other side of the two binding portions is joined to the corresponding leg plate portion 32 of the lead 20. The side is joined to the leg plate portion 33 on the corresponding side of the lid 20 by, for example, ultrasonic welding. Additionally, the backup leads 46 and 47 do not need to be provided. In one example, in each of the current collection tabs 15, one side of the two binding portions is on the main surface of the leg of the leg plate portion 32 on the corresponding side of the lead 20 without the backup lead 46 or the like being sandwiched between them. It is directly conjugated to (41). In addition, in each of the current collection tabs 15, the other side of the two binding portions is connected to the main surface of the leg of the leg plate portion 33 on the corresponding side of the lead 20 without the backup lead 47 or the like being sandwiched between them ( 43) is directly connected to it.

4 and 5 show one side of the pair of leads 20, the electrode group 2, and the configuration of their vicinity in a cross section perpendicular to or approximately perpendicular to the horizontal direction of the battery 1. In Figure 4, a cross section passing through a position spaced apart in the horizontal direction with respect to the through hole 37 of the lead 20 (the corresponding one connection position of the electrode terminal 16) is shown, and in Figure 5, the lead A cross section passing through the through hole 37 (at or approximately the center of the through hole 37) at 20 is shown. 3 to 5, etc., in each of the lids 20, the top surface 36 of the top plate portion 31 faces the side where the cover member 5 is located with respect to the height direction of the battery 1. It is formed in a flat or approximately flat shape. In one example, the top surface 36 of each lead 20 is formed parallel or substantially parallel to the inner surface of the cover member 5, and is parallel or substantially parallel to the depth direction and the transverse direction of the battery 1. is formed.

Additionally, in each of the lids 20, a concave portion 50 is formed on the lower surface 35 of the ceiling plate portion 31 toward the side where the upper surface 36 of the ceiling plate is located. In each of the leads 20 disposed in the internal cavity 8, the concave portion 50 formed on the lower surface of the ceiling plate 35 is concave toward the side where the cover member 5 is located with respect to the height direction, and the electrode group 2 ) is concave on the side opposite to the side where it is located. For this reason, in each of the leads 20, the recessed portion 50 is an electrode for each of the portions of the lower surface of the ceiling plate 35 other than the recessed portion 50 and the main surfaces of the legs 41 and 43 connected to the lower surface of the ceiling plate 35. It is concave on the side opposite to the side where group (2) is located.

Lid 20 On the ceiling plate lower surface 35 of each ceiling plate portion 31, the concave portion 50 is located along the plate longitudinal direction from the edge surface (ceiling plate inner edge surface) E1, and the edge surface E2 is located. It is formed towards the doing side. Accordingly, in each of the leads 20 disposed in the internal cavity 8, a concave portion 50 is provided on the lower surface of the ceiling plate 35 extending from the edge surface E1 toward the outer side in the horizontal direction of the battery 1. . In each of the leads 20, one end of the concave portion 50 with respect to the plate longitudinal direction is located on the edge surface E1, and an inner end of the concave portion 50 with respect to the transverse direction of the battery 1 (concave portion). The inner end of the portion) is located on the edge surface E1.

Additionally, each recessed portion 50 of the lead 20 has a recessed end surface 51. In each of the leads 20, an end opposite to the edge surface (ceiling plate inner edge surface) E1 of the concave portion 50 in the board longitudinal direction is formed by the concave end surface 51. Accordingly, in each of the leads 20, the outer end of the recessed portion 50 (recessed outer end) with respect to the horizontal direction of the battery 1 is formed by the recessed portion end surface 51. In each of the leads 20, the concave end surface 51 is located on the side where the edge surface E2 is located with respect to the through hole 37 (connection position of the electrode terminal 16), and the concave end surface ( 51) is located outside the through hole 37 in the horizontal direction of the battery 1. In addition, in this embodiment, in each of the leads 20, the concave end surface 51 is at a connection position to the top plate 31 of each of the leg plate portions 32 and 33 with respect to the horizontal direction of the battery 1. and is located on the side closer to the edge surface E1 and the through hole 37 with respect to the connection positions of each of the leg plate portions 32 and 33.

Since the structure is as described above, each of the leads 20 has an end opposite to the edge surface (ceiling plate inner edge surface) E1 of the recess 50, that is, an end of the recess 50. The end where the side surface 51 is formed is the connection position (through hole 37) of the electrode terminal 16 to the top plate portion 31 and the leg plate portion ( 32, 33) are located between the connection positions to each ceiling plate portion (31). Accordingly, on the lower surface 35 of the top plate 35 of each lead 20 disposed in the internal cavity 8, the concave portion 50 exceeds the connection position of the electrode terminal 16 to the top plate portion 31, and extends to the edge surface ( It is formed continuously from the ceiling plate inner edge surface (E1) toward the outer side in the horizontal direction. That is, in each of the leads 20, the concave portion 50 extends horizontally outward from the edge surface E1 to the concave end surface 51 located on the transverse outer side with respect to the through hole 37. It continues.

In addition, on the lower surface 35 of the ceiling plate of each lead 20, a relay portion 52 is formed between the concave end surface 51 of the concave portion 50 and the edge surface (outer edge surface of the ceiling plate) E2. do. On the lower surface 35 of the top plate of each lead 20, the relay portion 52 is adjacent to the concave portion 50 from the outer side in the horizontal direction of the battery 1, and has an edge surface E2 at the concave end surface 51. ), it is formed continuously toward the outside in the horizontal direction. In each of the leads 20, the main surfaces of the legs 41 of the leg plate 32 and the main surfaces of the legs 43 of the leg plate 33 are connected to the relay portion 52 of the lower surface of the ceiling plate 35. In each of the leads 20, the relay portion 52 of the lower surface of the top plate 35 is flat or substantially flat, facing toward the side where the electrode group 2 (bottom wall 6) is located with respect to the height direction of the battery 1. It is formed as a statue. In one example, the relay portion 52 of each lead 20 is formed parallel or substantially parallel to the depth direction and the horizontal direction of the battery 1.

Additionally, adjacent portions 55 and 56 are formed on the lower surface 35 of the ceiling plate of each lid 20. On the lower surface 35 of the top plate of each lead 20, the adjacent portion (first adjacent portion) 55 is a concave portion ( 50), and the adjacent portion (second adjacent portion) 56 is adjacent to the concave portion 50 from the opposite side to the adjacent portion 55 in the depth direction of the battery 1. On the lower surface 35 of the top plate of each lead 20, the adjacent portion 55 extends from the opening edge A1 of the concave portion 50 to the edge surface E3 in the depth direction of the battery 1 (lead 20). The adjacent portion 56 is formed continuously outward in the depth direction from the opening edge A2 of the concave portion 50 to the edge surface E4. In addition, in each of the leads 20, each of the adjacent portions 55 and 56 of the lower surface of the top plate 35 is on a plane or approximately a plane facing the side where the electrode group 2 is located with respect to the height direction of the battery 1. It is formed as a statue. In one example, in each of the leads 20, adjacent portions 55 and 56 are formed parallel or substantially parallel to the depth direction and the transverse direction of the battery 1.

On the lower surface 35 of the top plate of each lead 20, the concave portion 50 is located on the side opposite to the side on which the electrode group 2 is located with respect to each of the relay portion 52 and the adjacent portion 55 (cover member 5 ) is concave toward the side where ) is located. For this reason, in each of the leads 20, the concave portion 50 is sandwiched between the adjacent portions 55 and 56 in the depth direction and is adjacent to the inner side in the horizontal direction with respect to the relay portion 52, It is concave on the side opposite to the side where the electrode group 2 is located with respect to the height direction.

Additionally, in each of the leads 20, the recessed portion 50 is provided with a recessed bottom surface 57 that forms the bottom of the recessed portion 50. In each recess 50 of the lid 20, the bottom surface 57 of the recess extends from the edge surface (inside edge surface of the ceiling plate) E1 to the end surface of the recess 51 in the horizontal direction of the battery 1. It is formed continuously towards. For this reason, in each recess 50 of the lead 20, the bottom surface 57 of the recess passes through the through hole 37 (connection position of the electrode terminal 16 to the top plate portion 31) and extends in the horizontal direction. It is formed according to In each of the leads 20, the bottom surface 57 of the concave portion is formed in a planar or substantially planar shape that faces the side where the electrode group 2 is located with respect to the height direction of the battery 1. In one example, in each of the leads 20, the concave bottom 57 is formed parallel or substantially parallel to the top surface 36 of the top plate, and is parallel or substantially parallel to the depth direction and the transverse direction of the battery 1. is formed.

In each of the leads 20, there is a height direction (thickness direction of the lead 20) of the battery 1 from the opening (adjacent portions 55, 56) of the recessed portion 50 to the bottom surface of the recessed portion 57. The distance along is defined as the concave amount of the concave portion 50. In one example, in each lead 20, the concave amount of the concave portion 50 is approximately 0.5 mm. Since the concave portion 50 is formed as described above, in the top plate portion 31 of each lead 20, the plate thickness T1 in the area where the concave portion 50 is formed is It is thinner than the plate thickness T2 in areas other than the existing area (for example, the relay part 52 and adjacent parts 55, 56, etc.). And, in each of the leads 20, the plate thickness T1 of the top plate portion 31 in the area where the concave portion 50 is formed is the plate thickness of the leg plate portion 32 and the plate thickness of the leg plate portion 33. It is thin compared to its thickness.

Additionally, in one example, each lead 20 is formed from one plate member. In this case, the leg plate portion 32 that bends with respect to the top plate portion 31 and the leg plate portion 33 that bends with respect to the top plate portion 31 are formed by bending the plate member at corresponding locations. Additionally, a concave portion 50 is formed in the top plate lower surface 35 of the top plate portion 31 by performing press processing at corresponding locations in the plate member. As described above, when the concave portion 50 is formed by press working, in the top plate portion 31 of each lead 20, the hardness in the area where the concave portion 50 is formed is due to the fact that the concave portion is formed. It is harder than the hardness in areas other than the area where it is present (for example, the relay part 52 and adjacent parts 55 and 56, etc.). And, in each of the leads 20, the hardness of the top plate 31 in the area where the concave portion 50 is formed is harder than the hardness of the leg plate 32 and the leg plate 33, respectively. . Additionally, the concave portion 50 does not necessarily need to be formed by press working, and in one example, the concave portion 50 may be formed by cutting or the like.

On the lower surface 35 of the top plate of each lead 20, a step is formed between the relay portion 52 and the bottom surface 57 of the recessed portion by the recessed portion end surface 51. On the lower surface 35 of the top plate of each lead 20, the bottom surface 57 of the concave part is positioned at the relay portion 52 in the height direction of the battery 1 due to the step formed by the end surface 51 of the recessed part. In contrast, it is located on the opposite side to the side where the electrode group 2 is located, offset by the amount of the concave portion 50. Additionally, in examples such as those shown in FIG. 3 , in each of the leads 20, the concave end surface 51 is formed in a planar or substantially planar shape facing inward in the transverse direction of the battery 1, and It is formed parallel or approximately parallel to the depth direction and the height direction.

In addition, in each of the leads 20, the through hole 37 is opened toward the side where the cover member 5 is located in the upper surface of the ceiling plate 36, and is located on the bottom surface 57 of the concave portion of the lower surface of the ceiling plate 35. It opens toward the side where the electrode group 2 is located. For this reason, an opening for a through hole 37 is formed in the bottom surface 57 of the concave portion 50 in the lower surface 35 of the top plate of each lid 20. In addition, in each of the leads 20, the concave bottom 57 of the concave portion 50 is provided with an enlarged portion 58, and is provided in the depth direction of the battery 1 (the width direction of the top plate portion 31). The dimensions of the concave bottom surface 57 along , in the dimension enlarged portion 58, are enlarged compared to other portions of the concave bottom surface 57 (parts other than the dimension enlarged portion 58). For example, the dimension of the concave bottom 57 along the depth direction of the cell 1 in areas other than the dimensional enlarged portion 58 is equal to or approximately equal to the value (width) W1, and the dimension enlarged portion 58 is the same as the value (width) W1. The dimension of the concave bottom 57 along the depth direction of the cell 1 at (58) is larger than the value W1.

3 to 5, etc., in the concave bottom 57 of each lead 20, the enlarged portion 58 is positioned from the position S1 to the position S2 in the horizontal direction of the battery 1. is formed over At the bottom 57 of each recess of the lid 20, the position S1 is the inner end of the enlarged portion 58 in the transverse direction of the battery 1, and the position S2 is in the transverse direction of the battery. It becomes the outer end of the dimensionally enlarged portion 58. In addition, in the bottom surface 57 of each recess of the lid 20, the opening of the through hole 37 is located at positions S1 and S2 with respect to the horizontal direction of the battery 1 (the longitudinal direction of the top plate portion 31). and the through hole 37 opens toward the side where the electrode group 2 is located in the dimensional expansion portion 58. Then, at the bottom surface 57 of each recess of the lead 20, the caulked portion (plastically deformed portion) on one side of the electrode terminal 16 is joined to the enlarged portion 58, forming a through hole 37. ) is joined around the opening.

3 to 5, etc., in the dimensional enlarged portion 58 of each lead 20, a through hole 37 is formed in the horizontal direction of the battery 1 (the longitudinal direction of the top plate portion 31). The closer the position is to the center, the larger the size of the concave bottom 57 along the depth direction of the cell 1 is. Accordingly, in the dimensionally enlarged portion 58 of each lead 20, as the center of the through hole 37 approaches from each of the positions S1 and S2, the bottom surface 57 of the concave portion along the depth direction of the battery 1 The dimensions (width) of are expanded. In addition, the dimensionally enlarged portion 58 of each lead 20 is located in the depth direction of the battery 1 at a position passing through the center or approximately the center of the through hole 37 in the horizontal direction of the battery 1. The dimension of the bottom surface 57 of the concave portion becomes the value (maximum value) W2. For this reason, the dimensional expansion portion 58 of each lead 20 is directed toward the center of the through hole 37 from each of the positions S1 and S2 with respect to the horizontal direction of the battery 1, and the depth of the battery 1 The dimension of the concave bottom 57 along the direction expands from the value W1 to the value W2. In addition, in FIG. 4, a cross section passing through a position spaced laterally inward with respect to the dimensional enlarged portion 58 of the concave bottom 57 of the lead 20 is shown, and in FIG. 5, a cross section of the recessed bottom 57 of the lead 20 is shown. A cross section passing through the enlarged portion 58 of the concave bottom 57 is shown.

Additionally, each recessed portion 50 of the lead 20 has a pair of inclined surfaces 61 and 62 and a pair of stepped surfaces 65 and 66. On the lower surface 35 of the top plate of each lead 20, each of the inclined surfaces 61 and 62 extends continuously outward in the horizontal direction of the battery 1 from the edge surface E1 to the position S1, and is provided at the position It extends continuously outward in the horizontal direction of the battery 1 from (S2) to the concave end surface 51. Additionally, on the lower surface 35 of the top plate of each lead 20, inclined surfaces 61 and 62 are formed in the range between the positions S1 and S2 in the horizontal direction of the battery 1. On the lower surface 35 of the top plate of each lead 20, an inclined surface (first inclined surface) 61 is formed between the concave bottom 57 and the adjacent portion 55 in the depth direction of the battery 1, and the concave It is connected to the adjacent portion 55 at the opening edge A1 of the portion 50. In addition, on the lower surface 35 of the top plate of each lead 20, an inclined surface (second inclined surface) 62 is formed between the concave bottom 57 and the adjacent portion 56 with respect to the depth direction of the battery 1. , connected to the adjacent portion 56 at the opening edge A2 of the concave portion 50.

In each of the leads 20, the inclined surfaces 61 and 62 are inclined with respect to both the depth direction and the height direction of the battery 1 (the width direction and the plate thickness direction of the top plate portion 31). On the inclined surface 61 of the lower surface 35 of the top plate of each lead 20, the closer the position is to the adjacent portion 55, that is, the farther away it is from the bottom surface 57 of the concave portion, the closer it is to the height direction of the battery 1. It is located on the side closer to the electrode group 2. In addition, on the inclined surface 62 of the lower surface 35 of the top plate of each lead 20, the closer the position is to the adjacent portion 56, that is, the farther away from the bottom surface 57 of the concave portion is, the higher the height of the battery 1 is. It is located on the side closest to the electrode group 2 with respect to the direction. At the lower surface 35 of the top plate of each lead 20, there is a range between the edge surface E1 and the position S1 with respect to the transverse direction of the battery 1, and a position S2 with respect to the transverse direction of the battery 1. In each of the ranges between the concave end surfaces 51, the end opposite to the adjacent portion 55 of the inclined surface 61 and the end opposite to the adjacent portion 56 of the inclined surface 62 are each a concave portion. It is connected to the bottom surface (57).

In addition, on the lower surface 35 of the top plate of each lead 20, the dimensions of each of the inclined surfaces 61 and 62 along the depth direction of the battery 1 are equal to the edge surface E1 and the horizontal direction of the battery 1. Compared to the range between the position S1 and the range between the position S2 and the concave end surface 51 with respect to the transverse direction of the cell 1, respectively, the positions S1 and S2 with respect to the transverse direction of the cell 1 ) is small in the range between. And, on the lower surface 35 of the top plate of each lead 20, an inclined surface 61 along the depth direction of the battery 1 is formed in a range between the positions S1 and S2 with respect to the horizontal direction of the battery 1. 62) Each dimension decreases by the amount by which the dimension of the bottom surface 57 of the concave portion along the depth direction of the cell 1 is enlarged. In addition, in one example, on the lower surface 35 of the top plate of each lead 20, at a position passing through the center or approximately the center of the through hole 37 with respect to the horizontal direction of the battery 1, that is, the battery 1 ), the dimensions of each of the inclined surfaces 61 and 62 along the depth direction of the battery 1 become zero at a position where the dimension of the concave bottom 57 along the depth direction becomes the value (maximum value) W2.

On the lower surface 35 of the top plate of each lead 20, the step surfaces 65 and 66 are between the positions S1 and S2 with respect to the transverse direction of the battery 1 (the longitudinal direction of the top plate portion 31). It is formed only in the range, the range between the edge surface E1 and the position S1 with respect to the transverse direction of the battery 1, and the position S2 and the concave end surface 51 with respect to the transverse direction of the battery 1. is not formed in each of the ranges between. On the lower surface 35 of the top plate of each lead 20, in the range between the positions S1 and S2 with respect to the horizontal direction of the battery 1, the step surfaces 65 and 66 each have a concave bottom surface 57. ) is connected to the dimensionally enlarged portion 58. In addition, on the lower surface 35 of the ceiling plate of each lid 20, the end opposite to the enlarged portion 58 (concave bottom 57) of the step surface (first step surface) 65 is provided with an inclined surface 61. ) and the adjacent portion 55, and the end opposite to the dimensionally enlarged portion 58 (concave bottom 57) of the step surface (second step surface) 66 is connected to the inclined surface 62 and the adjacent portion. It is connected to (56).

In one example, in each of the leads 20, each of the step surfaces 65 and 66 is at the center of the through hole 37 when viewed from the side where the electrode group 2 is located with respect to the height direction of the battery 1. It is formed in an arc shape with the center or approximately the center. And, in each of the leads 20, each of the step surfaces 65 and 66 is parallel or substantially parallel to the height direction of the battery 1. As described above, since the inclined surfaces 61 and 62 and the stepped surfaces 65 and 66 are formed, on the lower surface 35 of the top plate of each lead 20, the bottom surface 57 of the concave portion is located in the height direction of the battery 1. With respect to each of the adjacent portions 55 and 56, the electrode group 2 is located on the opposite side, and is shifted by the amount of the concave portion 50. In addition, since the concave bottom 57 and the inclined surfaces 61 and 62 are formed as described above, each of the leads 20 has an edge surface E1 and a position S1 with respect to the horizontal direction of the battery 1. In the range between and the range between the position S2 and the concave end surface 51 with respect to the transverse direction of the battery 1, the concave portion 50 is recessed in a cross section perpendicular to or approximately perpendicular to the transverse direction. The shape is trapezoidal or approximately trapezoidal.

Additionally, the concave portion 50 of each lead 20 approaches the electrode group 2 from the side where the cover member 5 is located with respect to the height direction of the battery 1. For this reason, the concave portion 50 of each lead 20 is close to the outer surface of the end of the electrode group 2 on the side where the cover member 5 is located, that is, the curved surface 14 of the electrode group 2. , It faces the curved surface 14 of the electrode group 2 from the side where the cover member 5 is located. Here, a concave bottom 57 and inclined surfaces 61 and 62 are formed in each concave portion 50 of the lead 20, as described above. For this reason, the concave portion 50 of each lead 20 is formed in a shape according to the curved surface 14 of the electrode group 2, and is formed outside the end portion of the electrode group 2 on the side where the cover member 5 is located. It is formed in a shape according to the surface.

Additionally, in each of the leads 20, the concave portion 50 is close to the curved surface 14 of the electrode group 2, but the lower surface of the ceiling plate 35 including the concave portion 50 does not contact the curved surface 14. No. That is, the concave portion 50 of each lead 20 is close to the outer surface of the end of the electrode group 2 on the side where the cover member 5 is located, with a gap between it and the electrode group 2. do. In one example, in each lead 20, the gap between the concave portion 57 (concave bottom 57 and inclined surfaces 61 and 62) and the electrode group 2 is approximately 0.5 mm. Additionally, in the battery 1, a portion of the electrode group pressing member 23 contacts the electrode group 2, so that the electrode group 2 is positioned with respect to the height direction of the battery 1, thereby forming the battery 1. The movement of the electrode group 2 in the height direction is regulated. The portion of the electrode group pressing member 23 that comes into contact with the electrode group 2 is closer to the electrode group 2 than the concave portion 50 of each lead 20. Accordingly, a gap is maintained between the concave portion 50 of each lead 20 and the electrode group 2 by the contact portion of the electrode group pressing member 23 with the electrode group 2. .

In addition, in the negative electrode side lead 20A, the end (concave end surface 51) on the opposite side to the edge surface (top plate inner edge surface) E1 of the concave portion 50 is aligned in the horizontal direction of the battery 1. In contrast, it is preferably located outside the boundary position Ba between the negative electrode current collection tab 15A and the negative electrode active material-containing layer. In this case, also at the boundary position Ba of the electrode group 2, the concave portion 50 of the negative electrode side lead 20A is formed on the outer surface (curved surface) of the end of the electrode group 2 on the side where the cover member 5 is located. It is close to 14)). Similarly, in the positive electrode side lead 20B, the end (recessed end surface 51) on the opposite side to the edge surface E1 of the recessed portion 50 is connected to the positive electrode current collection tab 15B with respect to the horizontal direction of the battery 1. ) and the boundary position Bb of the positive electrode active material-containing layer is preferably located outside. In this case, also at the boundary position Bb of the electrode group 2, the concave portion 50 of the positive electrode side lead 20B is formed on the outer surface (curved surface) of the end of the electrode group 2 on the side where the cover member 5 is located. It is close to 14)).

As described above, in this embodiment, a concave portion 50 is formed on the lower surface 35 of the top plate of each lead 20 on the opposite side from the side where the electrode group 2 is located. And, in each of the leads 20, the concave portion 50 extends beyond the connection position (through hole 37) of the electrode terminal 16 to the top plate portion 31, and forms an edge surface (top plate inner edge surface) (E1). ) continues towards the outside in the horizontal direction. For this reason, it becomes possible to increase the space occupied by the electrode group 2 in the internal cavity 8 by the amount of the recess in the recess 50 of each lead 20. This makes it possible to increase the volume of the electrode group 2 and increase the capacity of the battery 1. In addition, in each of the leads 20, even if a concave portion 50 is formed in the top plate portion 31, a large cross-sectional area of the top plate portion 31 can be secured. For this reason, even if the recessed portion 50 is formed in the top plate portion 31 of each lead 20, the electrical resistance in the electrical path between the electrode group 2 and each of the electrode terminals 16 can be ensured low. do. Therefore, in this embodiment, the capacity of the battery 1 can be increased without increasing the electrical resistance in the electrical path between the electrode group 2 and each of the electrode terminals 16.

In addition, in this embodiment, the recessed portion 50 of each lead 20 is positioned on the side where the cover member 5 of the electrode group 2 is located by the recessed bottom surface 57 and the inclined surfaces 61 and 62. It is formed in a shape according to the outer surface of the end, that is, in a shape according to the curved surface 14 of the electrode group 2. As a result, it becomes possible to appropriately increase the size of the electrode group 2 in the height direction of the battery 1 by the amount of the concave portion 50 of each lead 20, so that the electrode group 2 ) It becomes possible to appropriately increase the volume. As a result, the capacity of the battery 1 is appropriately increased.

Additionally, in the electrode group 2, the boundary position Ba between the negative electrode current collection tab 15A and the negative electrode active material-containing layer in the horizontal direction of the battery 1, and the positive electrode current collection tab 15B and the positive electrode in the horizontal direction of the battery 1. The boundary position Bb of the active material-containing layer is defined. In the battery 1, in the recess 50 of each lead 20, the end (recess end surface 51) on the opposite side from the edge surface (ceiling plate inner edge surface) E1 is connected to the battery ( It is preferable to be located outside the boundary position (corresponding side of Ba and Bb) in the horizontal direction of 1). As a result, it becomes possible to more appropriately increase the dimension of the electrode group 2 in the height direction of the battery 1, and it becomes possible to more appropriately increase the volume of the electrode group 2.

In addition, the concave portions 50 of each lead 20 are close to the electrode group 2 from the side where the cover member 5 is located in the height direction, with a gap between them and the electrode group 2. do. As a result, contact of the lower surface 35 (recessed portion 50) of the top plate of each lead 20 with the electrode group 2 is effectively prevented. Here, when the battery 1 is used, etc., if the external container 3 expands due to the gas generated in the internal cavity 8, the electrode group 2 may vibrate with respect to the depth direction of the battery 1. there is. In this embodiment, as described above, contact of the bottom surface 35 of the top plate of each lead 20 with the electrode group 2 is effectively prevented, so that in the state in which the external container 3 is expanded, etc., the lead ( 20) Interference between the lower surface of each ceiling plate 35 and the vibrating electrode group 2 is effectively prevented. As a result, wear of the top plate portion 31 of each lead 20 and damage to the electrode group 2 are effectively prevented.

In addition, in each recess 50 of the lead 20, the bottom surface 57 of the recess passes through the through hole 37 (the connection position of the electrode terminal 16 to the top plate portion 31) along the horizontal direction. is formed In addition, in each recessed portion 50 of the lead 20, the bottom surface 57 of the recessed portion is formed in a planar or approximately planar shape facing the side where the electrode group 2 is located with respect to the height direction of the battery 1. And the opening of the through hole 37 is formed in the bottom surface 57 of the concave portion. Accordingly, in each of the leads 20, the caulked portion (plastically deformed portion) of the corresponding one side of the electrode terminal 16 is bonded to the bottom surface of the concave portion 57, so that the corresponding one side of the electrode terminal 16 The entire joint portion can be formed on the bottom surface 57 of the concave portion. That is, for each of the leads 20, the joint portion of the corresponding one side of the electrode terminal 16 can be formed on the same or approximately the same plane. As a result, the work efficiency in connecting each lead 20 to the corresponding side of the electrode terminal 16 is improved, and the work efficiency in manufacturing the battery 1 is improved. Additionally, each of the leads 20 is appropriately connected to the corresponding one side of the electrode terminal 16.

In addition, in each recessed portion 50 of the lead 20, the recessed bottom surface 57 has a dimension of the recessed bottom surface 57 along the depth direction of the battery 1 compared to other portions of the recessed bottom surface 57. It has a dimensionally enlarged portion 58 that is enlarged in comparison, and a through hole 37 is opened in the dimensionally enlarged portion 58. By forming the opening of the through hole 37 in the dimensional expansion portion 58, it becomes easy to join the corresponding one side of the electrode terminal 16 to the bottom surface 57 of the recess in each of the leads 20. As a result, the work efficiency in connecting each of the leads 20 to the corresponding side of the electrode terminal 16 is further improved, and each of the leads 20 is more suitable for the corresponding side of the electrode terminal 16. is connected properly.

In addition, in each of the leads 20, the end (recess end surface 51) on the opposite side to the edge surface (ceiling plate inner edge surface) E1 in the recess 50 is an electrode terminal in the horizontal direction. It is located between the connection position (through hole 37) to the top plate portion 31 of (16) and the connection position to the top plate portion 31 of each of the leg plate portions 32 and 33. For this reason, on the lower surface 35 of the top plate of each lead 20, each of the leg plate portions 32 and 33 is connected to the non-recessed relay portion 52 on the side opposite to the side where the electrode group 2 is located. . By connecting the leg plate portions 32 and 33 to the non-concave relay portion 52, in forming each of the leads 20, each of the leg plate portions 32 and 33 is bent with respect to the top plate portion 31. It becomes easier to bend. Accordingly, work efficiency in manufacturing each lead 20 is improved.

Additionally, on the lower surface 35 of the top plate of each lead 20, the corresponding one side of the pair of current collection tabs 15 may contact the relay portion 52. However, in the electrode group 2, each of the current collection tabs 15 is on one side of the lead 20, unlike the portion (coated portion) between the boundary positions Ba and Bb including the curved surface 14. Even if each of the current collection tabs 15 is deformed due to contact with the lower surface 35 of the top plate, the performance of the battery 1 is not significantly affected.

(variation example)

In the first modification shown in Fig. 6, in each of the lids 20, the end opposite to the edge surface (ceiling plate inner edge surface) E1 of the concave portion 50 is the edge surface (ceiling plate outer edge surface). It is located at (E2). For this reason, in this modification, in the top plate lower surface 35 of each lead 20, the recessed portion 50 is a connection position (through hole 37) of the electrode terminal 16 to the top plate portion 31, and Each of the leg plate portions 32 and 33 extends beyond the connection position to the top plate portion 31 and continues outward in the horizontal direction from the edge surface E1 to the edge surface E2. In this modified example as well, in the lower surface 35 of the top plate of each lead 20, the concave portion 50 is recessed on the side opposite to the side where the electrode group 2 is located.

Additionally, in one modification, only one side of the leg plate portions 32 and 33 may be provided for each of the leads 20. In this case as well, a concave portion 50 is formed on the lower surface 35 of the top plate of each lid 20 in the same manner as in any of the above-described embodiments.

Additionally, in the second modification shown in Fig. 7, a leg plate portion 70 is provided in place of the leg plate portions 32 and 33 in each of the leads 20. In each leg plate portion 70 of the lead 20, there is a plate longitudinal direction, a plate width direction that intersects (orthogonal or approximately perpendicular to) the plate length direction, and a plate width direction that intersects (orthogonal or approximately perpendicular to) both the plate longitudinal direction and the plate width direction. The plate thickness direction (approximately orthogonal) is defined. In an example such as Figure 7, in each of the leads 20, the length direction of each leg plate portion 70 coincides or approximately coincides with the plate thickness direction of the top plate portion 31, and the plate width of the leg plate portion 70 The direction coincides with or approximately coincides with the width direction of the top plate portion 31, and the plate thickness direction of the leg plate portion 70 coincides with or approximately coincides with the longitudinal direction of the top plate portion 31.

In each of the leads 20, the leg plate portion 70 is connected to the top plate portion 31 at a position outside the connection position of the electrode terminal 16 with respect to the horizontal direction of the battery 1, and is connected to the edge surface (ceiling plate). It is connected to the ceiling plate portion 31 at the outer edge surface (E2). Additionally, in each of the leads 20, the leg plate portion 70 is bent with respect to the top plate portion 31 at a connection position to the top plate portion 31, and is bent at a connection position to the top plate portion 31 (at a connection position to the top plate portion 31). It is installed extending along the height direction of the battery (1) at the bending position. In each of the lids 20, the leg plate portion 70 is bent toward the side where the bottom wall 6 is located with respect to the top plate portion 31, and the leg plate portion 70 is bent at a bending position with respect to the top plate portion 31. The bending line follows the depth direction of the cell 1 (the width direction of the ceiling plate portion 31).

Additionally, in each of the leads 20, the leg plate portion 70 is provided with a pair of leg main surfaces 71 and 72. In each leg plate portion 70 of the lid 20, the main surface of the leg 71 faces the inner side of the battery 1 in the horizontal direction and faces one side of the leg plate portion 70 in the plate thickness direction. In addition, in each leg plate portion 70 of the lid 20, the leg main surface 72 is on the opposite side from the leg main surface 71 with respect to the horizontal direction of the battery 1 (plate thickness direction of the leg plate portion 70). It faces outward in the horizontal direction of the battery 1. In each of the leads 20, at the connection position of the leg plate portion 70 to the top plate portion 31, the leg main surface 71 is connected to the top plate lower surface 35, and the leg main surface 72 is connected to the top plate upper surface 36. is connected to In each leg plate portion 70 of the lid 20, the leg main surface 72 faces the side where the peripheral wall 7 (the corresponding side of the side wall 11) is located, and faces the outer peripheral side of the internal cavity 8. heading towards In addition, in the leg plate portion 70 of each lead 20, the leg main surface 71 faces the inner circumference side of the internal cavity 8 and faces the side where the electrode group 2 is located. In each of the leads 20, the dimension between the leg main surfaces 71 and 72 is defined as the plate thickness of the leg plate portion 70.

Additionally, in each of the lids 20, the leg plate portion 70 is provided with edge surfaces (leg edge surfaces) E9 and E10. In each of the leg plate portions 70, an end on one side in the depth direction of the battery 1 (the width direction of the leg plate portion 70) is formed by the edge surface E9, and by the edge surface E10. , an end opposite to the edge surface E9 is formed in the depth direction of the battery 1. For this reason, in each of the lids 20, each of the leg main surfaces 71 and 72 extends along the depth direction from the edge surface E9 to the edge surface E10, and the leg plate portion 70 extends from the edge surface E9. ) to the edge surface E10 extending outward in the depth direction of the battery 1. In this modification, in each of the current collection tabs 15, the binding portion of the plurality of strip-shaped portions is formed at only one location. In each of the current collection tabs 15, the binding portion of the strip-shaped portion is joined to the corresponding side of the lid 20 and to the corresponding side of the edge surfaces E9 and E10 of the leg plate portion 70. Each of the current collection tabs 15 may be bonded directly to the corresponding side of the lead 20, or may be bonded to the corresponding side of the lead 20 with a backup lead or the like interposed therebetween.

In this modified example as well, on the lower surface 35 of the top plate 35 of each lead 20, the concave portion 50 exceeds the connection position (through hole 37) of the electrode terminal 16 to the top plate portion 31, It continues from the edge surface E1 outward in the horizontal direction. In addition, in this modification, in each of the leads 20, the end (recess end surface 51) on the opposite side to the edge surface (ceiling plate inner edge surface) E1 of the recess 50 is connected to the battery 1. ) is located between the connection position of the electrode terminal 16 to the top plate 31 and the connection position of the leg plate 70 to the top plate 31.

Additionally, in one modification, a leg plate portion 70 is provided in each of the leads 20, as in the second modification. And, on the lower surface 35 of the top plate of each lid 20, the concave portion 50 is formed continuously along the horizontal direction up to the connection position with the top plate portion 31 of the leg plate portion 70. In this case as well, on the lower surface 35 of the top plate 35 of each lead 20, the concave portion 50 extends beyond the connection position (through hole 37) of the electrode terminal 16 to the top plate portion 31 and forms an edge. It continues from the surface E1 outward in the horizontal direction.

In addition, in the above-described embodiment, etc., the recessed portion 50 of each lead 20 positions the cover member 5 of the electrode group 2 by the concave bottom 57 and the inclined surfaces 61 and 62. It is formed in a shape according to the outer surface of the end on the side where the lid 20 is located, but the concave portion 50 of each lead 20 is shaped according to the outer surface of the end on the side where the cover member 5 of the electrode group 2 is located. is not limited to this. In one modification, the inclined surfaces 61 and 62 are not provided in the recesses 50 of each lead 20, and the recesses 50 of each lead 20 are aligned in the horizontal direction (ceiling) of the battery 1. It is formed in a curved shape according to the curved surface 14 of the electrode group 2, except for the range between the positions S1 and S2 in the longitudinal direction of the plate portion 31. In this case, the recessed portion 50 of each lead 20 is connected to the battery ( 1) In a cross section perpendicular or substantially perpendicular to the horizontal direction (axial direction of the electrode group 2), it has an arc shape. However, in this modified example as well, each concave portion 50 of the lead 20 has a concave bottom 57 formed in a planar or substantially planar shape facing the side where the electrode group 2 is located. In addition, in each concave portion 50 of the lead 20, the concave bottom 57 is formed in a range between the positions S1 and S2 with respect to the horizontal direction of the battery 1, and is located at the edge of the electrode terminal 16. It is formed along the horizontal direction passing through the connection position (through hole 37) to the ceiling plate portion 31.

In addition, in one modification, the electrode group 2 has a stack structure, etc., and the curved surface 14 is not formed on the outer surface of the end of the electrode group 2 on the side where the cover member 5 is located. In this case as well, a concave portion 50 is formed in the lower surface 35 of the top plate of each lid 20. And, in each of the leads 20, the concave portion 50 is connected to other portions of the ceiling plate lower surface 35 and to the surface of the leg plate portions 32 and 33 (leg plate portion 70) connected to the ceiling plate lower surface 35. It is concave on the side opposite to the side where the electrode group 2 is located. In this case as well, on the lower surface 35 of the top plate 35 of each lead 20, the concave portion 50 extends beyond the connection position (through hole 37) of the electrode terminal 16 to the top plate portion 31 and forms an edge. It continues from the surface E1 outward in the horizontal direction. In addition, in the lower surface 35 of the top plate of each lead 20, the concave portion 50 is formed in a shape according to the outer surface of the end of the electrode group 2 on the side where the cover member 5 is located, and the electrode group (20) 2), it approaches the electrode group 2 from the side where the cover member 5 is located in the height direction with a gap between them.

In addition, in the configuration in which the curved surface 14 is not formed in the electrode group 2, on the lower surface 35 of the top plate 35 of each lead 20, the concave portion 50 is formed in the width direction of the top plate portion 31 (battery It may be formed over the entire dimension (full width) in the depth direction of (1). In this case, adjacent portions 55, 56, etc. are not formed on the lower surface 35 of the ceiling plate of each lead 20, and the concave portion 50 extends from the edge surface E3 to the edge surface E4. 31) is formed along the width direction. In this case as well, in each of the lids 20, the concave portion 50 is connected to other portions of the ceiling plate lower surface 35 and to the ceiling plate lower surface 35 of the leg plate portions 32 and 33 (leg plate portion 70). It is concave on the side opposite to the side where the electrode group 2 is located.

In addition, both the negative electrode side lead between the negative electrode current collection tab 15A and the negative electrode terminal 16A and the negative electrode side lead between the positive electrode current collection tab 15B and the positive electrode terminal 16B are used in the above-described embodiments and modifications, etc. There is no need to use the same configuration as any lead 20. That is, at least one of the negative electrode side lead and the positive electrode side lead may have the same configuration as any lead 20 in the above-described embodiments and modification examples.

According to at least one of these embodiments or examples, on the lower surface of the top plate of the lead top plate portion of the battery, the concave portion is concave on the side opposite to the side where the electrode group is located. The concave portion extends beyond the connection position of the electrode terminal to the top plate portion and is formed continuously from the inner edge surface of the top plate of the top plate portion toward the outer side in the horizontal direction. As a result, it is possible to provide a battery whose capacity can be increased without increasing the electrical resistance in the electrical path between the electrode group and the electrode terminal.

Although several embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, substitutions, and changes can be made without departing from the gist of the invention. These embodiments and their modifications are included in the scope and gist of the invention, as well as the invention described in the claims and their equivalents.

Claims (11)

An external container having a bottom wall and a peripheral wall and forming an internal cavity that opens on a side opposite to the side on which the bottom wall is located with respect to the height direction;
a cover member installed on the peripheral wall of the external container in a state that closes the opening of the internal cavity;
an electrode group provided with a current collection tab protruding outward in a horizontal direction intersecting the height direction and stored in the internal cavity of the external container;
an electrode terminal exposed to the outside on the outer surface of the cover member;
A lead electrically connecting the current collection tab of the electrode group and the electrode terminal.
Equipped with
The lead is disposed between the cover member and the electrode group in the internal cavity, is bent with respect to the top plate portion toward the side where the top plate portion to which the electrode terminal is connected and the bottom wall is located, and is joined to the current collection tab. It is provided with a leg board that can be
The ceiling plate portion has an inner edge surface of the ceiling plate forming an inner end of the ceiling plate portion in the horizontal direction, a lower surface of the ceiling plate facing the electrode group, and a lower surface of the ceiling plate on the opposite side from the side where the electrode group is located. It is concave and has a concave portion formed continuously from the inner edge surface of the ceiling plate toward the outer side in the horizontal direction beyond the connection position of the electrode terminal to the ceiling plate portion.
battery. According to paragraph 1,
The battery, wherein the concave portion is formed in a shape according to the outer surface of an end of the electrode group on the side where the cover member is located. According to claim 1 or 2,
The battery wherein the concave portion approaches the electrode group from the side where the cover member is located with respect to the height direction, with a gap between the concave portion and the electrode group. According to any one of claims 1 to 3,
The ceiling plate portion has an upper surface of the ceiling plate facing opposite to the lower surface of the ceiling plate,
A through hole is formed in the ceiling plate portion along the height direction from the upper surface of the ceiling plate to the lower surface of the ceiling plate, and into which the electrode terminal is inserted,
The concave portion is formed in a plane facing the side where the electrode group is located, and has a bottom surface of the concave portion formed along the horizontal direction past the connection position of the electrode terminal to the top plate portion,
The battery, wherein the through hole is opened in the bottom of the concave portion toward the side where the electrode group is located. According to clause 4,
The bottom of the concave portion has a dimension enlarged portion in which the dimension of the bottom of the concave portion along the depth direction intersecting both the height direction and the horizontal direction is enlarged compared to other portions of the bottom face of the concave portion,
The battery, wherein the through hole is opened in the dimensionally enlarged portion. According to any one of claims 1 to 5,
The leg plate portion is connected to the top plate portion at a position outside the connection position of the electrode terminal to the top plate portion with respect to the horizontal direction,
In the concave portion, an end opposite to the inner edge surface of the top plate is located between the connection position of the electrode terminal to the top plate portion and the connection position of the leg plate portion to the top plate portion in the horizontal direction. battery. According to any one of claims 1 to 6,
The battery wherein the plate thickness of the top plate portion in the area where the concave portion is formed is thinner than each of the plate thickness of the top plate portion and the plate thickness of the leg plate portion in areas other than the area where the concave portion is formed. According to any one of claims 1 to 7,
The battery wherein the hardness of the top plate portion in the area where the concave portion is formed is harder than the hardness of the top plate portion and the plate thickness of the leg plate portion in areas other than the area where the concave portion is formed. According to any one of claims 1 to 8,
The lower surface of the ceiling plate has a first adjacent portion adjacent to the concave portion from one side in the depth direction intersecting both the height direction and the horizontal direction, and a side opposite to the first adjacent portion with respect to the depth direction. and a second adjacent portion adjacent to the concave portion,
The concave portion is sandwiched between the first adjacent portion and the second adjacent portion in the depth direction, and is oriented on a side opposite to the side on which the electrode group is located with respect to the first adjacent portion and the second adjacent portion. Concave, omnipotent. According to any one of claims 1 to 9,
The electrode group includes a current collector and an active material-containing layer supported on the surface of the current collector,
The current collector of the electrode group includes the current collection tab as a portion on which the active material-containing layer is not supported,
The current collection tab protrudes outward in the horizontal direction with respect to the active material-containing layer in the electrode group,
A battery, wherein an end of the concave portion opposite to the inner edge surface of the top plate is located outside a boundary position between the current collection tab and the active material-containing layer in the horizontal direction. According to any one of claims 1 to 10,
The current collection tab includes a negative electrode current collection tab protruding in one side of the horizontal direction in the electrode group, and a positive electrode current collection tab protruding in the electrode group on a side opposite to the side on which the negative electrode current collection tab protrudes,
The electrode terminal includes a negative electrode terminal and a positive electrode terminal arranged to be spaced apart from the negative electrode terminal on the outer surface of the cover member,
A battery, wherein the lead is electrically connected between the negative electrode current collection tab and the negative electrode terminal, and the lead is electrically connected between the positive electrode current collection tab and the positive electrode terminal.

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