JP7327160B2 - Power storage device and power storage module - Google Patents

Description

The present invention relates to a power storage device and a power storage module.

Patent Document 1 describes a bipolar secondary battery. This bipolar secondary battery has a bipolar electrode in which a positive electrode layer is formed on one side of a current collector made of a rectangular SUS foil and a negative electrode layer is formed on the other side, and a separator holds an electrolyte. It has a configuration in which a plurality of sheets are arranged in series by stacking a plurality of electrolyte layers in between. In this bipolar secondary battery, a single cell layer is configured by a laminated structure in which an electrolyte layer is sandwiched between a positive electrode layer and a negative electrode layer. The current collector has an exposed portion where SUS is exposed. A lead wire is electrically connected to the exposed portion using a conductive adhesive.

JP 2008-117626 A

In the secondary battery as described above, it is important to ensure insulation between lead wires. For this purpose, for example, the insulation distance between the lead wires is ensured by offsetting the lead wire lead portions in the direction intersecting the stacking direction in the side surface of the secondary battery where the lead wire lead portions are provided. can be considered. However, in this case, the lead portions of the lead wires are dispersed over a wide area within the side surface of the secondary battery. As a result, the mounting area for electrical components such as harnesses attached to lead wires is increased. An increase in the mounting area of electrical components is a disadvantage in terms of size and cost.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an electricity storage module and an electricity storage device capable of suppressing an increase in mounting area for electrical components while ensuring insulation between lead wires.

A power storage module according to the present invention includes: a laminate including a plurality of bipolar electrodes laminated along a first direction; and a plurality of lead wires electrically connected to each of the plurality of bipolar electrodes, the bipolar electrodes comprising an electrode plate and electrode layers formed on both sides of the electrode plate. each of the plurality of sealing members is interposed between adjacent electrode plates at the outer edge of the electrode plates when viewed from the first direction, and each of the plurality of lead wires is positioned inside the laminate and at least two second A portion drawn out from the stack of portions overlaps in the first direction, and the second portion includes a conductive portion and an insulating portion covering the conductive portion.

In this power storage module, a lead wire is electrically connected to each of the plurality of bipolar electrodes forming the laminate. More specifically, the lead wire includes a first portion that is in contact with and electrically connected to the electrode plate of the bipolar electrode, and a sealing member that extends from the first portion and seals the side surface of the laminate. and a second portion that is pulled out of the laminate. The second portion includes a conductive portion and an insulating portion covering the conductive portion. Therefore, insulation between the lead wires is ensured even if the lead-out portions of the lead wires are not offset. As a result, at least two lead portions (second portions) of the lead wires can be overlapped in the stacking direction (first direction). Therefore, the expansion of the area where the lead-out portions of the lead wires are dispersed is suppressed by the overlap in the stacking direction. That is, an increase in the mounting area of the electrical component is suppressed.

In the electric storage module according to the present invention, the plurality of lead wires may be configured as a flexible substrate in which the conductive portion and the insulating portion are arranged in layers and integrated in at least the second portion. By using the flexible substrate as the lead wires in this manner, the above configuration can be easily and reliably realized.

In the electric storage module according to the present invention, the plurality of lead wires may be separated from each other in the first portion and integrated with each other in at least part of the second portion. In this case, handling of the lead wire is improved.

A power storage module according to the present invention includes a connector that is attached to the ends of second portions of a plurality of lead wires and holds the plurality of lead wires together, and the distance between the lead wires at the connector-side end of the lead wires is reduced. may be wider than the spacing between the first portions. In this case, the lead wires are held by the connector with relatively wide intervals, so that the insulation in the connector is reliably ensured.

In the power storage module according to the present invention, all the lead portions may overlap in the first direction. In this case, an increase in the mounting area of the electrical component is reliably suppressed.

Here, a power storage device according to the present invention includes the above-described power storage module, the drawer portion is arranged on the first side of the side surfaces of the laminate, and the pair of power storage modules have the first side facing the same direction. and the positions of the drawer portions on the first side face are symmetrical with respect to each other when viewed from the second direction intersecting the first side face.

This power storage device includes the power storage module described above. Therefore, an increase in the mounting area of the electrical component is suppressed while ensuring insulation between the lead wires. In particular, in this power storage device, the pair of power storage modules are configured such that the positions of lead wire lead-out portions on the side surfaces of the laminate are point symmetrical. Therefore, by arranging devices (for example, control devices) to which lead wires are to be connected at point-symmetrical reference positions, the lead wires of each power storage module can be shortened.

A power storage device according to the present invention includes a cooling member interposed between power storage modules and formed with a flow path for a cooling medium, and a control device provided on a first side surface. and the opening of the channel may be formed on the second side surface, which is a relatively wide side surface of the laminate. By mounting the control device on the relatively narrow first side surface in this way, it is possible to reduce the length of the lead wire and suppress the increase in size as described above. Furthermore, the cooling efficiency is improved by arranging the opening of the cooling medium flow path on the relatively wide second side surface.

ADVANTAGE OF THE INVENTION According to this invention, the electrical storage module and electrical storage apparatus which can suppress the increase in the attachment area of an electrical component can be provided, ensuring the insulation between lead wires.

FIG. 1 is a schematic side view showing a power storage device according to one embodiment. FIG. 2 is a schematic diagram of another side of the power storage device shown in FIG. 3 is a schematic cross-sectional view of the power storage module shown in FIGS. 1 and 2. FIG. 4 is a schematic cross-sectional view showing an enlarged part of the power storage module shown in FIG. 3. FIG. 2 is a schematic diagram of a wiring portion shown in FIG. 1; FIG. FIG. 6 is a schematic side view of power storage modules in a state of being stacked one another. FIG. 7 is a schematic side view showing a power storage module according to a modification.

An embodiment will be described in detail below with reference to the drawings. In the description of the drawings, the same or corresponding elements are denoted by the same reference numerals, and redundant description may be omitted. Each figure also shows an orthogonal coordinate system defined by the X, Y, and Z axes. The Z-axis direction is, for example, the vertical direction, and the X-axis and Y-axis directions are, for example, horizontal directions.

FIG. 1 is a schematic side view showing a power storage device according to one embodiment. FIG. 2 is a schematic diagram of another side of the power storage device shown in FIG. The power storage device 1 shown in FIGS. 1 and 2 can be used, for example, as a battery for various vehicles such as forklifts, hybrid vehicles, and electric vehicles. The power storage device 1 includes a laminate 2 , a pair of restraint members 5 that bind the laminate 2 , and a pair of insulating members 7 arranged between the laminate 2 and the restraint members 5 .

The laminate 2 includes a plurality (here, a pair) of power storage modules 11 stacked along the Z-axis direction, a positive electrode current collector plate 12 and a negative electrode current collector plate 13 provided so as to be in contact with the power storage module 11, have. Below, the Z-axis direction may be simply referred to as the “stacking direction”. The positive collector plate 12 is arranged between the adjacent power storage modules 11 . A flow path 12 a for a cooling medium such as air is formed in the positive electrode current collector plate 12 . Therefore, positive electrode current collector plate 12 also functions as a cooling member interposed between power storage modules 11 . The negative electrode current collector plates 13 are arranged at both ends of the laminate 2 in the lamination direction. The insulating member 7 is interposed between each of the negative electrode current collector plates 13 and the binding member 5 .

Each of the restraining members 5 is a member that applies a restraining force (load) along the stacking direction to the laminate 2 . Each of the binding members 5 may be made of, for example, a conductive metal (eg, an alloy such as copper, aluminum, titanium, nickel, or stainless steel). The restraining members 5 are connected to each other via connecting members 6 including fastening members such as bolts 6A and nuts 6B, for example. Therefore, each of the restraining members 5 is formed with a through-hole through which the bolt 6A is inserted.

Each of the insulating members 7 is, for example, a sheet-like member having insulating properties and has a substantially rectangular parallelepiped shape. Each of the insulating members 7 is in contact with the negative electrode current collector plate 13 here. That is, here, the power storage modules 11 are arranged so that the negative electrode terminal electrodes 19 coated with active material layers that become the negative electrode layers 23 described later are arranged at both ends of the laminate 2 in the stacking direction. Examples of materials for each of the insulating members 7 include polypropylene (PP), polyphenylene sulfide (PPS), and nylon 66 (PA66). At least one of the insulating members 7 may exhibit elasticity.

Subsequently, details of the power storage module 11 will be described with reference to FIG. 3 . 3 is a schematic cross-sectional view of the power storage module shown in FIGS. 1 and 2. FIG. As shown in FIG. 2, the power storage module 11 is a cell having a substantially rectangular parallelepiped shape. The power storage module 11 is, for example, a secondary battery such as a nickel-hydrogen secondary battery or a lithium-ion secondary battery. The power storage module 11 may be an electric double layer capacitor. The power storage module 11 may be an all-solid battery.

Here, the power storage module 11 is a bipolar lithium ion secondary battery. The power storage module 11 is sandwiched between the positive collector plate 12 and the negative collector plate 13 in the stacking direction, and can be electrically connected to the outside via the positive collector plate 12 and the negative collector plate 13 .

The power storage module 11 includes a laminate 14 and a plurality of seal members 15 . The laminate 14 has a plurality of bipolar electrodes (electrodes) 16 , a plurality of separators 17 , a positive terminal electrode 18 and a negative terminal electrode 19 . A plurality of bipolar electrodes 16 are stacked along the Z-axis direction (first direction) here. In this way, since the stacking direction of the bipolar electrodes 16 and the stacking direction of the power storage module 11 are the same here, the stacking direction of the bipolar electrodes 16 may also be simply referred to as the "stacking direction". The laminated body 14 has a side surface 14s along the lamination direction.

A positive terminal electrode 18 is stacked on the bipolar electrode 16 at one end of the stack 14 in the stacking direction. The negative terminal electrode 19 is stacked on the bipolar electrode 16 at the other end of the stack 14 in the stacking direction. Separators 17 are interposed between adjacent bipolar electrodes 16 , between bipolar electrode 16 and positive terminal electrode 18 , and between bipolar electrode 16 and negative terminal electrode 19 .

The bipolar electrode 16 has an electrode plate 21 , a positive electrode layer (electrode layer) 22 and a negative electrode layer (electrode layer) 23 . The electrode plate 21 includes main surfaces 21a and 21b that intersect the stacking direction. A positive electrode layer 22 is provided on the main surface 21a, and a negative electrode layer 23 is provided on the main surface 21b. That is, the bipolar electrode 16 includes electrode layers formed on both sides of the electrode plate 21 . The electrode plate 21 is sandwiched between the positive electrode layer 22 and the negative electrode layer 23 along the stacking direction. The bipolar electrode 16 is composed of a conductive plate having a positive electrode layer 22 formed on one surface and another conductive plate having a negative electrode layer 23 formed on one surface. They may be superimposed and formed so as to be in contact with each other.

The electrode plate 21 is a foil-shaped conductive member and has a substantially rectangular shape. The electrode plate 21 is, for example, metal foil or alloy foil. The metal foil is, for example, copper foil, aluminum foil, titanium foil, nickel foil, or the like. The alloy foil is, for example, stainless steel foil (for example, SUS304, SUS316, SUS301, SUS304, etc. specified in JIS G 4305:2015), plated steel plate (for example, specified in JIS G 3141:2005). cold-rolled steel plate (SPCC, etc.), plated stainless steel plate, or alloy foil of the above metals. When the electrode plate 21 is an alloy foil, or when the electrode plate 21 is a metal foil other than aluminum foil, the surface of the electrode plate 21 may be coated with aluminum.

The positive electrode layer 22 is a layered member containing a positive electrode active material, a conductive aid, and a binder, and has a substantially rectangular shape. The positive electrode active material of this embodiment is, for example, a composite oxide, metallic lithium, sulfur, or the like. The composition of the composite oxide includes, for example, at least one of iron, manganese, titanium, nickel, cobalt, and aluminum, and lithium. Examples of composite oxides include olivine-type lithium iron phosphate (LiFePO4). The binder serves to bind the active material or conductive aid to the surface of the current collector and maintain the conductive network in the electrode.

Binders include fluorine-containing resins such as polyvinylidene fluoride, polytetrafluoroethylene, and fluororubber; thermoplastic resins such as polypropylene and polyethylene; imide resins such as polyimide and polyamideimide; alkoxysilyl group-containing resins; Examples include acrylic resins such as meth)acrylic acid, styrene-butadiene rubber (SBR), carboxymethyl cellulose, alginates such as sodium alginate and ammonium alginate, water-soluble cellulose ester crosslinked products, and starch-acrylic acid graft polymers. can. These binders may be used singly or in combination. Conductive aids include, for example, acetylene black, carbon black, and graphite. The viscosity adjusting solvent is, for example, N-methyl-2-pyrrolidone (NMP).

The negative electrode layer 23 is a layered member containing a negative electrode active material, a conductive aid, and a binder, and has a substantially rectangular shape. The negative electrode active material of the present embodiment includes, for example, graphite, artificial graphite, highly oriented graphite, mesocarbon microbeads, carbon such as hard carbon and soft carbon, metal compounds, elements that can be alloyed with lithium or compounds thereof, boron added carbon and the like. Examples of elements that can be alloyed with lithium include silicon (silicon) and tin. The same conductive aid and binder as those used for the positive electrode layer 22 can be used.

The positive terminal electrode 18 includes an electrode plate 21 and a positive electrode layer 22 formed on one main surface 21 a of the electrode plate 21 . In the positive terminal electrode 18 , an electrode layer such as the negative electrode layer 23 is not formed on the other principal surface 21 b of the electrode plate 21 . The positive terminal electrode 18 is laminated on the bipolar electrode 16 such that one main surface 21a of the electrode plate 21 and the positive electrode layer 22 face the bipolar electrode 16 side (inside the laminate 14).

The negative terminal electrode 19 includes an electrode plate 21 and a negative electrode layer 23 formed on the other principal surface 21 b of the electrode plate 21 . In the negative terminal electrode 19 , an electrode layer such as the positive electrode layer 22 is not formed on one main surface 21 a of the electrode plate 21 . The negative terminal electrode 19 is stacked on the bipolar electrode 16 such that the other main surface 21b of the electrode plate 21 and the negative electrode layer 23 face the bipolar electrode 16 (inside the stack 14).

The separator 17 is a layered member that separates adjacent bipolar electrodes 16, between the bipolar electrode 16 and the positive terminal electrode 18, and between the bipolar electrode 16 and the negative terminal electrode 19, and has a substantially rectangular shape. ing. The separator 17 is a member that prevents short circuits between adjacent bipolar electrodes 16 , between the bipolar electrode 16 and the positive terminal electrode 18 , and between the bipolar electrode 16 and the negative terminal electrode 19 . The separator 17 is composed of the electrolyte contained in the positive electrode layer 22 and the negative electrode layer 23 . When the separator 17 is made of a solid electrolyte, the separator 17 may have a substantially rectangular plate shape.

The separator 17 is a porous film made of polyolefin resin such as polyethylene (PE) or polypropylene (PP). The separator 17 may be a woven fabric or non-woven fabric made of polypropylene, methyl cellulose, or the like. Separator 17 may be reinforced with a vinylidene fluoride resin compound.

The seal member 15 is a member that holds the plurality of bipolar electrodes 16, the plurality of separators 17, the positive terminal electrode 18, and the negative terminal electrode 19 included in the laminate 14, and has insulating properties. More specifically, the sealing member 15 holds the electrode plate 21 that constitutes the bipolar electrode 16 , the positive terminal electrode 18 and the negative terminal electrode 19 . The seal member 15 seals the side surfaces 14s of the laminate 14 and can also function as a short-circuit preventing member that prevents short-circuiting between the bipolar electrodes 16 .

The sealing member 15 has a frame shape (here, a rectangular frame shape) following the outer shape of the electrode plate 21 when viewed from the stacking direction. 21 are interposed. The sealing member 15 interposed between the electrode plates is joined (for example, welded) to the main surface 21a at the outer edge 21c of the electrode plate 21 . The seal member 15 may be further joined (eg, welded) to the main surface 21b of the electrode plate 21, or the seal members 15 may be joined (eg, welded) to each other.

On the other hand, at one end of the stack 14 in the stacking direction, the sealing member 15 is also arranged on the main surface 21b of the electrode plate 21 of the positive terminal electrode 18 facing the outside of the stack 14, and is also bonded to the main surface 21b ( For example, welding). Further, the sealing member 15 is arranged on the main surface 21a of the electrode plate 21 of the negative terminal electrode 19 facing the outside of the laminate 14, and is joined (for example, welded) to the main surface 21a.

A positive collector plate 12 is arranged in a region surrounded by the seal member 15 on the main surface 21 b of the electrode plate 21 of the positive terminal electrode 18 when viewed from the stacking direction. That is, at one end of the laminate 14 in the stacking direction, the sealing member 15 is arranged so as to surround the positive electrode current collector plate 12 when viewed from the stacking direction. A negative current collector plate 13 is arranged in a region surrounded by the seal member 15 on the main surface 21 a of the electrode plate 21 of the negative terminal electrode 19 when viewed from the stacking direction.

That is, the sealing member 15 is arranged at the other end of the laminate 14 in the stacking direction so as to surround the negative electrode current collector plate 13 when viewed from the stacking direction. A material for forming the sealing member 15 is a heat-resistant resin member or the like. Examples of heat-resistant resin members include polyimide, polypropylene (PP), polyphenylene sulfide (PPS), modified polyphenylene ether (modified PPE), PA66, and the like.

The positive electrode collector plate 12 is a conductive member that contacts the laminate 14 and has a plate shape. The positive collector plate 12 is adjacent to the power storage module 11 in the stacking direction. That is, the positive collector plate 12 is in contact with the electrode plate 21 of the positive terminal electrode 18 . The negative electrode current collector plate 13 is a conductive member that contacts the laminate 14 and has a plate shape. The negative electrode current collector plate 13 is adjacent to the power storage module 11 in the stacking direction, similarly to the positive electrode current collector plate 12 . That is, the negative collector plate 13 is in contact with the electrode plate 21 of the negative terminal electrode 19 .

The two power storage modules 11 are arranged such that the positive terminal electrodes 18 face each other. The positive collector plate 12 is arranged so as to contact these two positive terminal electrodes 18 facing each other. That is, in the present embodiment, one positive collector plate 12 functions as a positive collector plate for two power storage modules 11 .

In the power storage device 1, when the plurality of power storage modules 11 constituting the laminate 2 are viewed as one power storage cell group, the electrodes arranged at both ends of the power storage cell group in the stacking direction are both negative terminal electrodes 19, Alternatively, both are positive terminal electrodes 18 . Here, the electrodes arranged at both ends of the storage cell group in the stacking direction are both negative terminal electrodes 19 . In other words, the two power storage modules 11 are arranged so that the negative terminal electrodes 19 face each other (so that the positive terminal electrodes 18 face each other). Each of the two negative current collecting plates 13 is arranged so as to be in contact with each of the two negative terminal electrodes 19 facing each other.

Here, as shown in FIGS. 1 and 2, the power storage device 1 includes a control device 50 and a base 51 on which the control device 50 is mounted. The base 51 is arranged on the side surface 14 s of the laminate 14 so as to span the pair of restraining members 5 and is fixed to the restraining members 5 . The controller 50 is attached to the base 51 . In the power storage device 1, the pair of power storage modules 11 are stacked such that the side surfaces (first side surfaces) 14s of the stacks 14 are oriented in the same direction. A device 50 is attached. Control device 50 is electrically connected to each of power storage modules 11 via wiring portion 30 . A connector 31 provided at one end of the wiring portion 30 is connected to the control device 50, and another connector 52 for external connection is provided.

4 is a schematic cross-sectional view showing an enlarged part of the power storage module shown in FIG. 3. FIG. FIG. 5 is a schematic diagram of the wiring portion shown in FIG. As shown in FIGS. 3-5, wiring portion 30 includes a plurality of lead wires 24 . Each of the plurality of lead wires 24 is electrically connected to at least each of the plurality of bipolar electrodes 16 . In other words, the power storage module 11 has a plurality of lead wires 24 electrically connected to each of the bipolar electrodes 16 . Lead 24 includes a first portion 24A and a second portion 24B. The first portion 24A is located inside the laminate 14 . The first portion 24A is in contact with and electrically connected to the electrode plate 21 .

Here, the first portion 24A is joined to the main surface 21a of the electrode plate 21. As shown in FIG. The bonding between the first portion 24A and the electrode plate 21 may be, for example, adhesion using a conductive adhesive or welding. Alternatively, the first portion 24A may be joined to the electrode plate 21 by welding the seal member 15 while maintaining contact with the electrode plate 21 . The second portion 24B is continuous with the first portion 24A, extends from the first portion 24A and is pulled out of the laminate 14 through the seal member 15 .

On the other hand, the lead wire 24 includes a conductive portion 25 and an insulating portion 26 covering the conductive portion 25 . As an example, the lead wire 24 is a flexible substrate (FPC) in which a conductive portion 25 and an insulating portion 26 are arranged in layers and integrated. In this case, each of the lead wires 24 has a long sheet shape. Also, in this case, the conductive portion 25 can be integrated with the insulating portion 26 by being formed by printing. In the first portion 24</b>A, the insulating portion 26 is removed to expose the conductive portion 25 , and the conductive portion 25 is in contact with the electrode plate 21 . The insulating portion 26 remains in the second portion 24B. That is, the second portion 2B is electrically insulated from the outside.

Each of the plurality of lead wires 24 may be separated from each other or may be integrated with each other. The connector 31 collectively holds the plurality of lead wires 24 at the end of the second portion 24B opposite to the first portion 24A. In the example of FIG. 5(a), the plurality of lead wires 24 are separated from each other at the first portion 24A side portion of the first portion 24A and the second portion 24B, and at the connector 31 side portion of the second portion 24B. They are integrated with each other at the ends. Thus, when at least a part of the lead wire 24 is integrated, the integrated portion of the wiring portion 30 becomes a wide sheet. For this reason, the wiring portion 30 may be folded, for example, in a bellows shape for each lead wire 24 in the sheet-like portion.

On the other hand, in the example of FIG. 5B, the lead wires 24 are separated from each other throughout the first portion 24A and the second portion 24B. In particular, in the example of FIG. 5B, the interval between the lead wires 24 at the end of the lead wire 24 on the connector 31 side (the end of the second portion 24B opposite to the first portion 24A) is the first It is wider than the interval between the portions 24A.

FIG. 6 is a schematic side view showing power storage modules in a state of being stacked one another. In FIG. 6, the configuration of the power storage device 1 other than the power storage module 11 is omitted. As shown in FIG. 6, lead portions 24C of the second portions 24B of the lead wires 24 extending from the laminate 14 are collectively provided on the side surface 14s of the laminate 14. As shown in FIG. Here, all the lead portions 24C are arranged in a row in the stacking direction and overlap each other. The drawn-out portion 24C is unevenly distributed in a region R on one side of the side surface 14s when viewed from the direction intersecting the side surface 14s (the second direction, which is the Y-axis direction here).

Here, the power storage device 1 and the power storage module 11 are elongated in the Y-axis direction with respect to the X-axis direction (see FIGS. 1 and 2). For this reason, hereinafter, the Y-axis direction, which is the second direction, will be referred to as the “longitudinal direction” for convenience, and the X-axis direction, which is the third direction intersecting the first and second directions, will be referred to as the “lateral direction” for convenience. It may be called "direction".

The pair of power storage modules 11 are arranged such that the side surfaces 14s of the laminate 14 are oriented in the same direction as described above, and the positions of the drawer portions 24C on the side surfaces 14s are point symmetric when viewed in the longitudinal direction. stacked on top of each other. As a result, in the pair of power storage modules 11, the regions R where the lead portions 24C are unevenly distributed are spaced apart in the X-axis direction. In the power storage device 1, the control device 50 is arranged in a region between the pair of regions R when viewed in the longitudinal direction on the side surface 14s. Therefore, the distance from the drawer portion 24C of one power storage module 11 to the control device 50 and the distance from the drawer portion 24C of the other power storage module 11 to the control device 50 are approximately the same (shortest).

In addition, as shown in FIGS. 1 and 2 , the side surface 14 s of the laminate 14 is a relatively narrow surface among the plurality of side surfaces of the laminate 14 . The laminate 14 has another side surface (second side surface) 14r that connects the side surfaces 14s. The side surface 14 r is a relatively wide surface among the plurality of side surfaces of the laminate 14 . That is, the lead-out portion 24C and the control device 50 are provided on the relatively narrow side surface 14s side of the laminate 14, and the opening 12b of the flow path 12a provided in the positive electrode current collector plate 12 is provided on the relatively wide side surface. It is formed on the 14r side.

The wiring portion 30 described above can be provided in the electric storage module 11 by stacking the bipolar electrodes 16 and the like while sandwiching the first portion 24A of the lead wire 24 between the bipolar electrodes 16 and the like.

As described above, in power storage module 11 , lead wire 24 is electrically connected to each of the plurality of bipolar electrodes 16 forming laminate 14 . More specifically, the lead wire 24 includes a first portion 24A that is in contact with and electrically connected to the electrode plate 21 of the bipolar electrode 16, and extends from the first portion 24A and extends across the side surface 14s of the laminate 14. and a second portion 24B drawn out of the laminate 14 via the sealing member 15 for sealing. Second portion 24</b>B includes conductive portion 25 and insulating portion 26 covering conductive portion 25 . Therefore, insulation between the lead wires 24 is ensured even if the lead portions 24C of the lead wires 24 are not offset. As a result, the lead portions 24C (second portions 24B) of at least two lead wires 24 can be overlapped in the stacking direction. Therefore, the expansion of the area where the lead portions 24C of the lead wires 24 are dispersed is suppressed by the overlap in the stacking direction. That is, an increase in the mounting area of the electrical component is suppressed.

Further, in the power storage module 11, the plurality of lead wires 24 may be configured as a flexible substrate in which the conductive portions 25 and the insulating portions 26 are arranged in layers and integrated at least in the second portion 24B. . By using a flexible substrate as the lead wire 24 in this manner, the above configuration can be easily and reliably realized.

Moreover, in the power storage module 11, the plurality of lead wires 24 may be separated from each other in the first portion 24A and may be integrated with each other in at least part of the second portion 24B. In this case, handling of the lead wire 24 is improved.

The power storage module 11 also includes a connector 31 that is attached to the ends of the second portions 24B of the plurality of lead wires 24 and holds the plurality of lead wires 24 collectively. The interval between the lead wires 24 at the end of the lead wire 24 on the connector 31 side may be wider than the interval between the first portions 24A. In this case, the lead wires 24 are held by the connector 31 with relatively wide intervals, so that insulation in the connector is reliably ensured.

Furthermore, in the storage module 11, all the lead portions 24C overlap in the stacking direction. Therefore, an increase in the mounting area of the electrical component is reliably suppressed.

Here, the power storage device 1 includes the power storage module 11 described above. In addition, the lead portion 24C is arranged on the side surface 14s of the laminate 14. As shown in FIG. The pair of power storage modules 11 are arranged so that the side surfaces 14s are oriented in the same direction, and the positions of the drawer portions 24C on the side surfaces 14s are point-symmetrical when viewed from the longitudinal direction that intersects the side surfaces 14s. Laminated.

The power storage device 1 includes the power storage module 11 described above. Therefore, the insulation between the lead wires 24 is ensured, and an increase in the mounting area of the electrical component is suppressed. In particular, in the power storage device 1, the positions of the lead portions 24C of the lead wires 24 on the side surfaces 14s of the laminate 14 of the pair of power storage modules 11 are symmetrical. Therefore, the lead wires 24 of the power storage module 11 can be shortened by arranging the devices (for example, the control device 50 ) to which the lead wires 24 are connected at point-symmetrical reference positions. Furthermore, it becomes possible to make a pair of electrical storage modules 11 into the same design.

Further, the power storage device 1 includes a cooling member (positive electrode current collector plate 12) interposed between the power storage modules 11 and formed with a cooling medium flow path 12a, and a control device 50 provided on the side face 14s. ing. The side surface 14s is a relatively narrow side surface of the laminate 14, and the opening 12b of the flow path 12a is formed on the side surface 14r, which is a relatively wide side surface of the laminate 14. there is By mounting the control device 50 on the relatively narrow side surface 14s in this way, it is possible to suppress shortening of the lead wire 24 and increase in size as described above. Furthermore, the cooling efficiency is improved by arranging the openings 12b of the cooling medium flow paths 12a on the relatively wide side surfaces 14r.

The above embodiment describes one mode of the present invention. Therefore, the present invention is not limited to the power storage device 1 and power storage module 11 described above, and can be arbitrarily modified.

For example, in the above-described embodiment, an example was described in which the lead portions 24C of all the lead wires 24 overlap in the stacking direction. However, in the electric storage module 11, at least the lead portions 24C of the pair of lead wires 24 should overlap in the stacking direction. In the example of FIG. 7, the plurality of lead wires 24 are divided into a plurality of groups by a predetermined number, and the lead portions 24C in each group are sequentially offset in the width direction. On the other hand, between the groups, the lead portions 24C overlap in the stacking direction. Therefore, in this example, lead portions 24C corresponding to the number of divisions of the lead wire 24 overlap in the stacking direction.

In the above-described embodiment, an example in which the flow path 12a for the cooling medium is formed in the positive electrode current collector plate 12 has been described. good.

Further, in the above embodiment, an example in which the lead wire 24 (and the wiring portion 30) is made of FPC was given, but the lead wire 24 includes the conductive portion 25 and the insulating portion covering the conductive portion 25 at least in the second portion 24B. 26, and may be a flat cable or wire harness.

Furthermore, the first portion 24A may be composed of a plurality of members. For example, the lead wire 24 and the electrode plate 21 may be connected via another conductive member. In this case, the conductive portion 25 of the lead wire 24 and another conductive member may constitute the first portion 24A.

Reference Signs List 1 power storage device 11 power storage module 12 positive current collector plate (cooling member) 14 laminate 14s side surface (first side surface) 14r side surface (second side surface) 15 sealing member 16 Bipolar electrode 21 Electrode plate 22 Positive electrode layer (electrode layer) 23 Negative electrode layer (electrode layer) 24 Lead wire 24A First portion 24B Second portion 24C Drawer portion 25 ... Conductive part 26... Insulating part 31... Connector 50... Control device.

Claims (7)

a laminate including a plurality of bipolar electrodes laminated along a first direction;
a plurality of sealing members provided to each of the plurality of bipolar electrodes so as to seal the side surfaces of the laminate along the first direction;
a plurality of lead wires electrically connected to each of the plurality of bipolar electrodes;
with
The bipolar electrode includes an electrode plate and an electrode layer formed on a pair of main surfaces of the electrode plate intersecting the first direction ,
each of the plurality of sealing members is interposed between the adjacent electrode plates at outer edge portions of the electrode plates when viewed from the first direction,
Each of the plurality of lead wires includes a first portion located inside the laminate and electrically connected to and in contact with one of the electrode plates, and the seal member extending from the first portion. a second portion pulled out of the laminate from
at least two of the second portions extending from the laminate overlap in the first direction;
the lead portion includes a conductive portion and an insulating portion covering the conductive portion;
the laminate includes terminal electrodes of different polarities at one end and the other end in the first direction;
The sealing member is provided on the main surface facing the outside of each electrode plate of the terminal electrode,
each of the plurality of sealing members includes a portion overlapping the electrode plate and a portion positioned outside the outer edge of the electrode plate when viewed from the first direction;
The sealing members adjacent to each other in the first direction are welded to each other at portions located outside the outer edge of the electrode plate,
the first portion of the lead wire is welded to the main surface of the electrode plate and covered with the sealing member;
The second portion of the lead wire is pulled out from a portion where the sealing members are welded together.
storage module. The plurality of lead wires are configured as a flexible substrate in which the conductive portion and the insulating portion are arranged in layers and integrated at least in the second portion,
The power storage module according to claim 1. The plurality of lead wires are separated from each other in the first portion and integrated with each other in at least a portion of the second portion.
The power storage module according to claim 2. a connector attached to the ends of the second portions of the plurality of lead wires and holding the plurality of lead wires together;
the interval between the lead wires at the connector-side end of the lead wire is wider than the interval between the first portions;
The power storage module according to any one of claims 1 to 3. all the lead portions overlap in the first direction;
The power storage module according to claim 1 or 2. A pair of power storage modules stacked in a first direction via current collector plates ,
Each power storage module includes:
a laminate including a plurality of bipolar electrodes laminated along a first direction;
a plurality of sealing members provided to each of the plurality of bipolar electrodes so as to seal the side surfaces of the laminate along the first direction;
a plurality of lead wires electrically connected to each of the plurality of bipolar electrodes;
with
The bipolar electrode includes an electrode plate and electrode layers formed on both sides of the electrode plate,
each of the plurality of sealing members is interposed between the adjacent electrode plates at outer edge portions of the electrode plates when viewed from the first direction,
Each of the plurality of lead wires includes a first portion located inside the laminate and electrically connected to and in contact with one of the electrode plates, and the seal member extending from the first portion. a second portion pulled out of the laminate from
at least two of the second portions extending from the laminate overlap in the first direction;
the second portion includes a conductive portion and an insulating portion covering the conductive portion;
The drawer portion is arranged on a first side surface of the side surfaces of the laminate,
The pair of power storage modules are configured so that the first side surfaces face the same direction, and the positions of the drawn portions on the first side surface are point-symmetrical when viewed from a second direction that intersects with the first side surface. are laminated to each other so that
the laminate includes terminal electrodes of different polarities at one end and the other end in the first direction;
The pair of power storage modules are arranged such that the terminal electrodes of the same polarity face each other via the current collector plates,
The terminal electrodes of the same polarity facing each other are in contact with the current collector plate,
Separate current collector plates having the same polarity are arranged at both ends of the pair of power storage modules in the first direction, respectively.
storage device. a cooling member interposed between the power storage modules and having a flow path for a cooling medium;
A control device provided on the first side,
the first side surface is a relatively narrow side surface of the side surfaces of the laminate;
The opening of the flow path is formed on a second side surface, which is a relatively wide side surface of the side surfaces of the laminate,
The power storage device according to claim 6 .

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