JP7156071B2 - ELECTRODE UNIT AND METHOD FOR MANUFACTURING ELECTRODE UNIT - Google Patents

Description

One aspect of the present invention relates to an electrode unit and a method for manufacturing the electrode unit.

A bipolar battery described in Patent Document 1 is known as a secondary battery. In this bipolar battery, bipolar electrodes each having a positive electrode formed on one surface of a current collector and a negative electrode formed on the other surface are stacked with an electrolyte layer interposed therebetween. An insulating sealing layer is provided between the current collectors.

Japanese Patent Application Laid-Open No. 2005-190713

The separator contained in the electrolyte layer is permeable to the electrolyte while being placed between adjacent current collectors (electrode plates) to prevent short circuits between them. Between the separator and the resin sealing layer (frame), there may be a gap in the direction intersecting the stacking direction. In this case, a short circuit may occur between the adjacent electrode plates through the gap. Therefore, in such a bipolar battery as described above, it is required to appropriately dispose the separator between the electrode plates.

An object of one aspect of the present invention is to provide an electrode unit in which a separator can be appropriately arranged between electrode plates.

An electrode unit according to one aspect of the present invention is an electrode unit that includes a rectangular electrode and a sealing body that is joined to an edge of the electrode, wherein the sealing body is each of the rectangular electrodes formed by the electrode. The sheet bodies are composed of a plurality of sheet bodies corresponding to the sides, and the sheet bodies include a first portion including a portion joined to the electrodes and a second portion folded back toward the first portion and arranged side by side. Between the sheet bodies, an overlapping portion is formed in which the ends of the first portions are overlapped with each other, and the second portion is folded back to the first portion avoiding the overlapping portion, and the width direction intersecting the direction of the corresponding side is formed. At, the length of the first portion is greater than the length of the second portion.

In the above electrode unit, among the plurality of sheet bodies, the overlapping portions are formed between adjacent sheet bodies. Since the second portion is folded back to the first portion avoiding the overlapping portion, a frame-shaped region having a substantially uniform thickness can be formed by the region in which the first portion and the second portion are laminated. The length of the first portion is greater than the length of the second portion in the width direction that intersects the direction along the corresponding side. In other words, the edge of the second portion is located inside the sheet body relative to the edge of the first portion in the width direction. In such a configuration, the separator can be arranged to overlap the first portion between the edge of the second portion and the edge of the first portion. In this case, occurrence of a short circuit between adjacent electrode plates is effectively suppressed.

Also, the position of the folding line for folding the second portion may be outside the outer edge of the electrode. With this configuration, the outer edges of the electrodes are prevented from being exposed to the outside of the sealing body.

Also, both the first portion and the second portion may be rectangular, and the length of the first portion may be greater than the length of the second portion in the direction of the corresponding sides. Moreover, the overlapping portion may have a square shape in plan view. With such a configuration, a rectangular frame-shaped sealing body can be easily configured by four sheet members.

In addition, in the sheet body, the lower base of the trapezoidal first portion and the lower base of the trapezoidal second portion are connected to each other, and the inner angle between the lower base of the first portion and the legs is 45 degrees. Larger, the sum of the interior angle between the bottom and the leg in the first portion and the interior angle between the bottom and the leg in the second portion may be 90 degrees. In this configuration, since the inner angle formed by the lower base and the legs in the first portion is larger than 45 degrees, when a plurality of sheet bodies are arranged in a rectangular frame, the ends of the adjacent sheet bodies are overlap. Further, since the sum of the interior angle formed between the bottom sole and the leg in the first portion and the interior angle formed between the bottom sole and the leg in the second portion is 90 degrees, when the second portion is folded back, the second portion is Duplicates can be avoided.

Also, the sheet body has a first portion in which the lower base of the trapezoidal portion and one long side of the rectangular portion are connected to each other, and a base having a lower base connected to the other long side of the rectangular portion in the first portion. The trapezoidal portion has a second portion, and the interior angle between the base and the legs of the trapezoidal portion in the first portion and the interior angle between the bottom and the legs in the second portion may both be 45 degrees. . In this case, the legs of the folded second portion and the legs of the first portion of the adjacent seat body can be parallel.

In sheet bodies corresponding to adjacent sides, the position of the midpoint of the short side of the rectangular portion of one sheet body may overlap with the position of the midpoint of the short side of the rectangular portion of the other sheet body. With this configuration, the position of the leg of the folded second portion can match the position of the leg of the first portion of the adjacent seat body.

An electrode unit manufacturing method according to one aspect of the present invention includes a step of arranging a plurality of sheet bodies corresponding to each side of a rectangular electrode on each corresponding side, and a step of joining the arranged sheet bodies to the electrodes. and a step of folding back a second portion formed continuously with the first portion toward the first portion including the portion to be joined to the electrode of the joined sheet bodies. In the step of overlapping the ends of the first portions of the sheet bodies corresponding to the adjacent sides to form an overlapping portion and folding back, the second portion is folded back to the first portion while avoiding the overlapping portion. , the second portion is folded back so that the edge of the second portion is located inside the sheet body relative to the edge of the first portion in the width direction intersecting the direction of the corresponding side.

According to one aspect of the present invention, it is possible to provide an electrode unit in which a separator can be appropriately arranged between electrode plates.

1 is a schematic cross-sectional view showing an example of a power storage device including power storage modules; FIG. 2 is a schematic cross-sectional view showing an electricity storage module that constitutes the electricity storage device of FIG. 1; FIG. It is a flowchart which shows the manufacturing method of an electrical storage apparatus. FIG. 4 is a plan view for explaining an electrode unit; FIG. 4 is a plan view for explaining an electrode unit; It is a top view which shows an electrode unit. FIG. 4 is a cross-sectional view showing an electrode unit; It is a flowchart which shows the manufacturing method of an electrode unit. FIG. 11 is a plan view for explaining an electrode unit according to another example; FIG. 10 is a plan view for explaining the electrode unit in the example of FIG. 9; FIG. 10 is a plan view showing the electrode unit of the example of FIG. 9; FIG. 10 is a plan view for explaining an electrode unit according to still another example; FIG. 13 is a plan view for explaining the electrode unit in the example of FIG. 12; FIG. 13 is a plan view showing the electrode unit of the example of FIG. 12; FIG. 10 is a plan view for explaining an electrode unit according to still another example; FIG. 16 is a plan view for explaining the electrode unit in the example of FIG. 15; FIG. 16 is a plan view showing the electrode unit of the example of FIG. 15; FIG. 16 is a diagram for explaining an example of a manufacturing process of the electrode unit of the example of FIG. 15;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of the drawings, the same reference numerals are used for the same or equivalent elements, and overlapping descriptions are omitted.

[First embodiment]
An example of a power storage device including power storage modules will be described with reference to FIG. FIG. 1 is a schematic cross-sectional view showing one embodiment of a power storage device. A power storage device 1 shown in FIG. 1 is used, for example, as a battery for various vehicles such as forklifts, hybrid vehicles, and electric vehicles. The power storage device 1 includes a module stack 2 including a plurality of stacked power storage modules 4 and a restraining member 3 that applies a restraining load to the module stack 2 in the stacking direction of the module stack 2 .

The module laminate 2 includes a plurality of (here, three) power storage modules 4 and a plurality of (here, four) conductive plates 5 . The power storage module 4 is a bipolar battery and has a rectangular shape when viewed from the stacking direction. The storage module 4 is, for example, a secondary battery such as a nickel-hydrogen secondary battery or a lithium-ion secondary battery, or an electric double layer capacitor. In the following description, a nickel-metal hydride secondary battery is exemplified.

Electricity storage modules 4 adjacent to each other in the stacking direction are electrically connected via conductive plates 5 . The conductive plates 5 are arranged between the power storage modules 4 adjacent to each other in the stacking direction and outside the power storage module 4 located at the end of the stack. A positive electrode terminal 6 is connected to one of the conductive plates 5 arranged outside the storage module 4 positioned at the end of the stack. A negative electrode terminal 7 is connected to the other conductive plate 5 arranged outside the storage module 4 positioned at the end of the stack. The positive electrode terminal 6 and the negative electrode terminal 7 are pulled out, for example, from the edge of the conductive plate 5 in a direction intersecting the stacking direction. The power storage device 1 is charged and discharged by the positive terminal 6 and the negative terminal 7 .

It is to be noted that the conductive plate 5 may not be arranged on the outer side in the stacking direction of the power storage module 4 located at the stack end. In this case, the power storage module 4 may be the outermost layer (stack outermost layer) of the laminate of the power storage module 4 and the conductive plate 5 in the power storage device 1 . When the power storage modules 4 form the outermost layer of the stack, the positive terminal 6 is connected to one power storage module 4 positioned at the end of the stack, and the negative terminal 7 is connected to the other power storage module 4 positioned at the end of the stack. It will happen.

Inside the conductive plate 5, a plurality of flow paths 5a for circulating a coolant such as air are provided. The flow path 5a extends along a direction that intersects (perpendicularly), for example, the stacking direction and the lead-out direction of the positive electrode terminal 6 and the negative electrode terminal 7, respectively. The conductive plate 5 functions not only as a connecting member that electrically connects the storage modules 4, but also as a radiator plate that dissipates the heat generated in the storage modules 4 by circulating the coolant through the flow paths 5a. have a combination of functions. In the example of FIG. 1, the area of the conductive plate 5 when viewed from the stacking direction is smaller than the area of the power storage module 4, but from the viewpoint of improving heat dissipation, the area of the conductive plate 5 is less than the area of the power storage module. 4 , or may be larger than the area of power storage module 4 .

The restraining member 3 is composed of a pair of end plates 8 that sandwich the module stack 2 in the stacking direction, and fastening bolts 9 and nuts 10 that fasten the end plates 8 together. The end plate 8 is a rectangular metal plate having an area slightly larger than the area of the storage module 4 and the conductive plate 5 when viewed in the stacking direction. A film F having electrical insulation is provided on the surface of the end plate 8 on the module laminate 2 side. The film F insulates between the end plate 8 and the conductive plate 5 . In addition, when the storage module 4 constitutes the outermost layer of the stack, the film F provides insulation between the end plate 8 and the storage module 4 .

An insertion hole 8 a is provided in the edge of the end plate 8 at a position outside the module stack 2 . The fastening bolt 9 is passed from the insertion hole 8a of one end plate 8 toward the insertion hole 8a of the other end plate 8, and the tip portion of the fastening bolt 9 protruding from the insertion hole 8a of the other end plate 8 has a , a nut 10 is screwed. As a result, the storage module 4 and the conductive plate 5 are sandwiched between the end plates 8 to form a module laminate 2 as a unit, and a binding load is applied to the module laminate 2 in the stacking direction.

Next, the configuration of the power storage module 4 will be described in detail. 2 is a schematic cross-sectional view showing the internal configuration of the power storage module shown in FIG. 1. FIG. As shown in FIG. 2 , the power storage module 4 includes an electrode laminate 11 and a resin sealing body 12 that seals the electrode laminate 11 . The electrode stack 11 is composed of a plurality of electrodes stacked along the stacking direction D<b>1 of the storage module 4 with separators 13 interposed therebetween. These electrodes include a stack of multiple bipolar electrodes 14 , a negative terminal electrode 18 and a positive terminal electrode 19 .

The bipolar electrode 14 has an electrode plate 15 including one surface 15a and the other surface 15b opposite to the one surface 15a, a positive electrode 16 provided on the one surface 15a, and a negative electrode 17 provided on the other surface 15b. ing. The positive electrode 16 is a positive electrode active material layer formed by coating the electrode plate 15 with a positive electrode active material. The negative electrode 17 is a negative electrode active material layer formed by coating the electrode plate 15 with a negative electrode active material. In the electrode stack 11 , the positive electrode 16 of one bipolar electrode 14 faces the negative electrode 17 of another bipolar electrode 14 that is adjacent on one side in the stacking direction D<b>1 with the separator 13 interposed therebetween. In the electrode laminate 11 , the negative electrode 17 of one bipolar electrode 14 faces the positive electrode 16 of another bipolar electrode 14 adjacent to the other in the stacking direction D<b>1 with the separator 13 interposed therebetween.

The negative terminal electrode 18 has an electrode plate 15 and a negative electrode 17 provided on the other surface 15 b of the electrode plate 15 . The negative terminal electrode 18 is arranged at one end in the stacking direction D1 so that the other surface 15b faces the central side of the electrode stack 11 in the stacking direction D1. One surface 15a of the electrode plate 15 of the negative terminal electrode 18 constitutes one outer surface in the stacking direction of the electrode laminate 11, and is electrically connected to one conductive plate 5 (see FIG. 1) adjacent to the electricity storage module 4. It is connected. The negative electrode 17 provided on the other surface 15b of the electrode plate 15 of the negative terminal electrode 18 faces the positive electrode 16 of the bipolar electrode 14 at one end in the stacking direction D1 with the separator 13 interposed therebetween.

The positive terminal electrode 19 has an electrode plate 15 and a positive electrode 16 provided on one surface 15 a of the electrode plate 15 . The positive terminal electrode 19 is arranged at the other end in the stacking direction D1 such that one surface 15a faces the center of the electrode stack 11 in the stacking direction D1. The positive electrode 16 provided on one surface 15a of the positive terminal electrode 19 faces the negative electrode 17 of the bipolar electrode 14 at the other end in the stacking direction D1 with the separator 13 interposed therebetween. The other surface 15b of the electrode plate 15 of the positive terminal electrode 19 constitutes the other outer surface in the stacking direction of the electrode laminate 11, and is electrically connected to the other conductive plate 5 (see FIG. 1) adjacent to the electricity storage module 4. It is connected.

The electrode plate 15 is made of metal such as nickel or nickel-plated steel plate, for example. As an example, the electrode plate 15 is a rectangular metal foil made of nickel. The edge portion 15c of the electrode plate 15 has a rectangular frame shape and is an uncoated region where the positive electrode active material and the negative electrode active material are not coated. Examples of the positive electrode active material forming the positive electrode 16 include nickel hydroxide. Examples of negative electrode active materials that constitute the negative electrode 17 include hydrogen storage alloys. In this embodiment, the formation area of the negative electrode 17 on the other surface 15 b of the electrode plate 15 is one size larger than the formation area of the positive electrode 16 on the one surface 15 a of the electrode plate 15 .

The separator 13 is formed in a sheet shape, for example. Examples of the separator 13 include porous films made of polyolefin resins such as polyethylene (PE) and polypropylene (PP), and woven or nonwoven fabrics made of polypropylene, methyl cellulose, and the like. The separator 13 may be reinforced with a vinylidene fluoride resin compound. Note that the separator 13 is not limited to a sheet shape, and may be bag-shaped.

The sealing body 12 is made of, for example, an insulating resin, and is formed into a rectangular tubular shape as a whole. The sealing body 12 is provided on the side surface 11 a of the electrode laminate 11 so as to surround the edge 15 c of the electrode plate 15 . The encapsulant 12 holds the edge 15c on the side surface 11a. The sealing body 12 includes a plurality of first sealing portions 21 joined to the edge portion 15c of the electrode plate 15, and surrounds the first sealing portions 21 from the outside along the side surface 11a. and a second sealing portion 22 joined to each of the . The first sealing portion 21 and the second sealing portion 22 are, for example, an insulating resin having alkali resistance. Examples of materials constituting the first sealing portion 21 and the second sealing portion 22 include polypropylene (PP), polyphenylene sulfide (PPS), modified polyphenylene ether (modified PPE), and the like.

The first sealing portion 21 is provided continuously over the entire circumference of the edge portion 15c on the one surface 15a of the electrode plate 15, and has a rectangular frame shape when viewed from the stacking direction D1. As will be described later, the first sealing portion 21 is formed by four sheet bodies 121 arranged to form a rectangular frame shape. In this embodiment, the first sealing portion 21 is provided not only for the electrode plate 15 of the bipolar electrode 14 but also for the electrode plate 15 of the negative terminal electrode 18 and the electrode plate 15 of the positive terminal electrode 19 . In the negative terminal electrode 18, the first sealing portion 21 is provided on the edge 15c of the one surface 15a of the electrode plate 15. In the positive terminal electrode 19, the edges of both the one surface 15a and the other surface 15b of the electrode plate 15 are provided. A first sealing portion 21 is provided at 15c.

The first sealing portion 21 is welded to the one surface 15a of the electrode plate 15 by, for example, ultrasonic waves or heat, and is airtightly joined. The first sealing portion 21 is, for example, a film having a predetermined thickness in the stacking direction D1. The inside of the first sealing portion 21 is positioned between the edge portions 15c of the electrode plates 15 adjacent to each other in the stacking direction D1. The outside of the first sealing portion 21 protrudes beyond the edge of the electrode plate 15 , and the tip portion thereof is embedded in the second sealing portion 22 . The first sealing portions 21 adjacent to each other along the stacking direction D1 may be separated from each other or may be in contact with each other. Further, the outer edge portions of the first sealing portion 21 may be joined together by, for example, hot plate welding.

A region where the electrode plate 15 and the first sealing portion 21 overlap is a bonding region K between the electrode plate 15 and the first sealing portion 21 . In the joint region K, the surface of the electrode plate 15 is roughened. The roughened area may be only the bonding area K, but in this embodiment, the entire surface of the electrode plate 15 is roughened. Roughening can be achieved by forming a plurality of protrusions by, for example, electroplating. By forming a plurality of projections, the molten resin enters between the plurality of projections formed by surface roughening at the bonding interface between the electrode plate 15 and the first sealing portion 21, thereby exhibiting an anchor effect. be. Thereby, the bonding strength between the electrode plate 15 and the first sealing portion 21 can be improved. The projections formed during surface roughening have, for example, a shape that tapers from the proximal side to the distal side. As a result, the cross-sectional shape between adjacent projections becomes an undercut shape, making it possible to enhance the anchor effect.

The second sealing portion 22 is provided outside the electrode laminate 11 and the first sealing portion 21 and constitutes an outer wall (housing) of the power storage module 4 . The second sealing portion 22 is formed, for example, by injection molding of resin, and extends over the entire length of the electrode laminate 11 along the lamination direction D1. The second sealing portion 22 has a rectangular frame shape extending with the stacking direction D1 as an axial direction. The second sealing portion 22 is welded to the outer surface of the first sealing portion 21 by heat during injection molding, for example.

The first sealing portion 21 and the second sealing portion 22 form an internal space V between adjacent electrodes and seal the internal space V. As shown in FIG. More specifically, the second sealing portion 22, together with the first sealing portion 21, is arranged between the bipolar electrodes 14 adjacent to each other along the stacking direction D1 and between the negative electrode termination electrodes 18 adjacent to each other along the stacking direction D1. and the bipolar electrode 14, and between the positive terminal electrode 19 and the bipolar electrode 14 adjacent to each other along the stacking direction D1. As a result, airtight internal spaces V are formed between the adjacent bipolar electrodes 14, between the negative terminal electrode 18 and the bipolar electrode 14, and between the positive terminal electrode 19 and the bipolar electrode 14, respectively. ing. This internal space V accommodates an electrolytic solution (not shown) containing an alkaline solution such as an aqueous potassium hydroxide solution. The electrolytic solution is impregnated in the separator 13 , the positive electrode 16 and the negative electrode 17 . A side surface of the sealing body 12 is provided with an injection port for injecting an electrolytic solution into the internal space V. As shown in FIG.

Next, a manufacturing process of the power storage device 1 described above will be described.

FIG. 3 is a flow chart showing an example of a manufacturing process of the power storage device 1. As shown in FIG. As shown in FIG. 3, the manufacturing process of the power storage device 1 includes an electrode unit manufacturing process (S01), a stacking process (S02), a sealing body forming process (S03), an injection process (S04), and an assembly process. and a step (S05).

In the electrode unit manufacturing step S01, the electrode unit 30 is manufactured by an electrode unit manufacturing method which will be described later. The electrode unit 30 includes a bipolar electrode 14 and a rectangular frame-shaped first sealing portion 21 joined to an edge portion 15 c of the bipolar electrode 14 .

In the stacking step S02, the electrode units 30 are stacked via the separators 13 to obtain a stack. Further, the electrode laminate 11 is obtained by further laminating the negative terminal electrode 18 and the positive terminal electrode 19 on the laminate end of the laminate of the electrode unit 30 . In lamination, a rectangular frame-shaped first sealing portion 21 is joined to the edge portion 15c of each of the electrode plates 15 of the negative terminal electrode 18 and the positive terminal electrode 19 by welding or the like.

In the sealing body forming step S03, the sealing body 12 is formed by forming the second sealing portion 22 on the electrode laminate 11 by injection molding, for example. Specifically, the electrode laminate 11 obtained in the lamination step S02 is placed in a mold, and a resin material having fluidity is poured into the mold to form the second sealing on the side surface of the electrode laminate 11. forming part 22; The first sealing portions 21 of the electrode laminate 11 are joined together by the second sealing portion 22 to obtain the sealing body 12 . At this time, an injection port for injecting the electrolytic solution into the internal space V is formed on the side surface of the sealing body 12 .

In the injection step S<b>04 , an electrolytic solution is injected into each of the internal spaces V of the electrode laminate 11 . Here, the electrolytic solution is injected into the internal space V through the injection port provided on the side surface of the sealing body 12 . After injecting the electrolytic solution, the injection port is sealed with a sealing material or the like to obtain the power storage module 4 . In place of the sealing material, a pressure regulating valve or the like may be provided at the injection port.

In the assembly step S05, first, a plurality of power storage modules 4 are stacked with conductive plates 5 interposed therebetween. At this time, it is preferable to previously connect the positive electrode terminal 6 to the conductive plate 5 arranged on one side in the stacking direction, and to previously connect the negative electrode terminal 7 to the conductive plate 5 arranged on the other side. Next, a pair of end plates 8 , 8 are arranged at both ends of the electric storage module 4 in the stacking direction via a film F having electrical insulation. Then, the fastening bolt 9 is inserted through the insertion hole 8 a of the end plate 8 , and the nut 10 is screwed to the tip of the fastening bolt 9 projecting from the end plate 8 . As a result, the power storage device 1 is obtained by unitizing the plurality of power storage modules 4 .

Next, the configuration of the electrode unit 30 will be described. FIG. 4 is a plan view for explaining the electrode unit, showing the correspondence between each side of the bipolar electrode 14 and the sheet body 121. As shown in FIG. FIG. 5 is a plan view for explaining the electrode unit, showing a state in which the sheet body 121 joined to the bipolar electrodes 14 is unfolded. FIG. 6 is a plan view showing the electrode unit. FIG. 7 is a cross-sectional view showing an electrode unit. 4 to 6, illustration of the positive electrode 16 and the negative electrode 17 is omitted.

The electrode unit 30 in this embodiment is configured by the bipolar electrode 14 and the first sealing portion (sealing body) 21 joined to the edge portion 15c of the bipolar electrode 14 . As shown in FIG. 4 , the example first sealing portion 21 is configured by four sheet members 121 . These four sheet members 121 correspond to the sides of the rectangle formed by the bipolar electrodes 14 . That is, the four sheet bodies 121 are composed of two sheet bodies 121L corresponding to the long sides of the bipolar electrodes 14 and two sheet bodies 121S corresponding to the short sides of the bipolar electrodes 14. FIG.

The sheet body 121L includes a first portion 122L and a second portion 123L. The first portion 122L includes a portion joined to the edge 15c of the bipolar electrode 14. As shown in FIG. The second portion 123L is a portion folded back toward the first portion 122L. In the illustrated example, the boundary between the first portion 122L and the second portion 123L is indicated by a chain double-dashed line. The second portion 123L is folded back toward the first portion 122L along the two-dot chain line (folding line 121a).

The first portion 122L and the second portion 123L in the illustrated example are both rectangular. The length of the first portion 122L is greater than the length of the second portion 123L in the direction (width direction) intersecting the direction along the corresponding side. That is, in the direction along the short side of the bipolar electrode 14, the length L1 of the first portion 122L is longer than the length L2 of the second portion 123L.

Also, the length of the first portion 122L is greater than the length of the second portion 123L in the direction along the corresponding side. That is, in the direction along the long side of the bipolar electrode 14, the length L3 of the first portion 122L is longer than the length L4 of the second portion 123L. As an example, the length L3 of the first portion 122L is longer than the length of the long side of the bipolar electrode 14, and the length L4 of the second portion 123L is shorter than the length of the long side of the bipolar electrode 14. In the illustrated example, the center position of the first portion 122L and the center position of the second portion 132L match in the direction along the corresponding side. That is, in the long side direction of the bipolar electrode 14, both ends of the first portion 122L protrude beyond the second portion 123L. As an example, the amount of projection of the first portion 122L may be the same as the length L1 of the first portion 122L in the direction along the short side of the bipolar electrode 14 . Also, the amount of protrusion of the first portion 122L may be greater than the length L1.

The sheet body 121S includes a first portion 122S and a second portion 123S. The first portion 122S includes a portion joined to the edge 15c of the bipolar electrode 14. As shown in FIG. The second portion 123S is a portion folded back toward the first portion 122S. In the illustrated example, the boundary between the first portion 122S and the second portion 123S is indicated by a chain double-dashed line. The second portion 123S is folded back toward the first portion 122S along the two-dot chain line (folding line 121a).

Both the first portion 122S and the second portion 123S in the illustrated example are rectangular. The length of the first portion 122S is greater than the length of the second portion 123S in the direction (width direction) intersecting the direction along the corresponding side. That is, in the direction along the long side of the bipolar electrode 14, the length L5 of the first portion 122S is longer than the length L6 of the second portion 123S.

Also, the length of the first portion 122S is greater than the length of the second portion 123S in the direction along the corresponding side. That is, in the direction along the short side of the bipolar electrode 14, the length L7 of the first portion 122S is longer than the length L8 of the second portion 123S. As an example, the length L7 of the first portion 122S is longer than the length of the short side of the bipolar electrode 14, and the length L8 of the second portion 123S is shorter than the length of the short side of the bipolar electrode 14. Also, in the illustrated example, the center position of the first portion 122S and the center position of the second portion 123S match in the direction along the corresponding side. That is, in the direction along the short side of the bipolar electrode 14, both ends of the first portion 122S protrude more than the second portion 123S. As an example, the amount of protrusion of the first portion 122S may be the same as the length L5 of the first portion 122S in the direction along the long side of the bipolar electrode 14 . Also, the amount of protrusion of the first portion 122S may be greater than the length L5.

In this embodiment, the widthwise length L1 of the first portion 122L of the sheet body 121L is the same as the widthwise length L5 of the first portion 122S of the sheet body 121S. Further, the widthwise length L2 of the second portion 123L of the sheet body 121L is the same as the widthwise length L6 of the second portion 123S of the sheet body 121S.

The four sheet members 121 described above are joined to the edge portions 15c of the corresponding sides of the bipolar electrode 14, respectively. As shown in FIG. 5, in the present embodiment, a portion of the first portion 122L of the sheet body 121L is joined along the edge 15c of the long side of the bipolar electrode 14. As shown in FIG. The second portion 123L of the sheet body 121L does not overlap the bipolar electrode 14. As shown in FIG. That is, the boundary between the first portion 122L and the second portion 123L indicated by a two-dot chain line is located outside the bipolar electrode 14. As shown in FIG.

A part of the first portion 122S of the sheet body 121S is joined along the edge 15c of the short side of the bipolar electrode 14. As shown in FIG. The second portion 123S of the sheet body 121S does not overlap the bipolar electrode 14. As shown in FIG. That is, the boundary between the first portion 122S and the second portion 123S indicated by a two-dot chain line is located outside the bipolar electrode 14. As shown in FIG.

Sheet body 121L and sheet body 121S corresponding to adjacent sides of bipolar electrode 14 form overlapping portion 125 in which the end of first portion 122L and the end of first portion 122S overlap each other. In the illustrated example, the end of the first portion 122S of the sheet body 121S overlaps the end of the first portion 122L of the sheet body 121L. In the overlapping portion 125, the corner of the first portion 122S of the sheet body 121S and the corner of the first portion 122L of the sheet body 121L match. In this case, the overlapping portion 125 has a square shape in plan view.

As shown in FIGS. 6 and 7, in the electrode unit 30, the second portion 123S of the sheet body 121S is folded back toward the first portion 122S avoiding the overlapping portion 125. As shown in FIGS. Similarly, the second portion 123L of the sheet body 121L is folded back toward the first portion 122L avoiding the overlapping portion 125. As shown in FIG. The folded second portion 123S and the second portion 123L may be in contact with the overlapping portion 125 or may be separated from the overlapping portion 125 .

The first sealing portion 21 made up of four sheet members 121 has a rectangular frame shape in plan view. The first sealing portion 21 surrounds the edge portion 15c of the electrode plate 15 and is joined to the edge portion 15c. An inner edge 25 s of the first sealing portion 21 is located inside the peripheral edge 15 d of the electrode plate 15 . The first sealing portion 21 partially has two layers by folding the sheet body 121 at a position outside the peripheral edge 15 d of the electrode plate 15 . That is, the first sealing portion 21 includes a first layer 25 formed by first portions 122L and 122S joined to the bipolar electrode 14, and a second portion 123L folded back toward the first layer 25 side and laminated. and a second layer 27 formed by 123S. The second layer 27 is provided on the surface 25 a of the first layer 25 opposite to the bonding surface with the bipolar electrode 14 . The inner peripheral edge of the first layer 25 (that is, the inner edge 25 s of the first sealing portion 21 ) is located inside the inner edge 27 s of the second layer 27 . The separator 13 can be bonded to the inner peripheral edge portion 25b including the inner edge 25s of the first layer 25 . That is, the second layer 27 functions as a spacer layer for arranging the separator 13 between the stacked electrode units 30 . In the electrode unit 30 , a joint region between the first sealing portion 21 and the electrode plate 15 is formed in a region from the inner edge 25s of the first sealing portion 21 to the peripheral edge 15d of the electrode plate 15 .

Next, the electrode unit manufacturing method by the electrode unit manufacturing step S01 will be described. FIG. 8 is a flow chart showing an example of the electrode unit manufacturing process. The electrode unit manufacturing process S01 in this embodiment includes an arrangement process S11, a joining process S12, and a folding process S13.

In the arranging step S11, four sheet members 121 corresponding to each side of the rectangular bipolar electrode 14 are arranged on each corresponding side. In this step, the overlapping portions 125 are formed by overlapping the ends of the first portions 122S and 122L of the sheet bodies 121 corresponding to the adjacent sides.

In the joining step S<b>12 , the arranged sheet body 121 is joined to the bipolar electrode 14 . As a method for joining the first sealing portion 21 and the bipolar electrode 14, for example, ultrasonic welding or heat welding may be used. The first sealing portion 21 is similarly joined to the negative terminal electrode 18 and the positive terminal electrode 19 as well.

In the folding step S<b>13 , the second portions 123</b>L, 123</b>S are folded toward the first portions 122</b>L, 122</b>S including the portions to be joined to the bipolar electrodes 14 of the joined sheet body 121 . In this step, the second portions 123L and 123S are folded back to the first portions 122L and 122S while avoiding the overlapping portion 125. As shown in FIG. In this case, the edges of the second portions 123L and 123S (that is, the inner edges 27s) are closer to the sheet body 121 than the edges of the first portions 122L and 122S (that is, the inner edges 25s) in the width direction that intersects the direction of the corresponding side. Fold the second part so that it lies on the inside. Thereby, the first layer 25 is formed by the first portions 122L and 122S of the sheet body 121, and the second layer 27 is formed by the second portions 123L and 123S.

In the electrode unit 30 described above, the overlapping portion 125 is formed by adjacent sheet members 121 among the four sheet members 121 . The second portions 123L and 123S are folded back to the first portions 122L and 122S avoiding the overlapping portion 125. As shown in FIG. Thereby, a frame-shaped region having a substantially uniform thickness can be formed by the region where the first portions 122L, 122S and the second portions 123L, 123S are laminated and the overlapping portion 125. As shown in FIG. The widthwise lengths L1 and L5 of the first portions 122L and 122S are greater than the widthwise lengths L2 and L6 of the second portions 123L and 123S. Therefore, a stepped portion is formed by folding the second portions 123L and 123S. In such a configuration, the separator 13 can be arranged between the edges of the second portions 123L and 123S (ie inner edges 27s) and the edges of the first portions 122L and 122S (ie inner edges 25s). In this case, occurrence of a short circuit between adjacent bipolar electrodes 14 is effectively suppressed.

Moreover, the folding line 121 a for folding the second portion may be positioned outside the peripheral edge 15 d of the bipolar electrode 14 . In this configuration, the peripheral edge 15 d of the bipolar electrode 14 is prevented from being exposed to the outside of the first sealing portion 21 .

Also, the first portions 122L, 122S and the second portions 123L, 123S are both rectangular. The lengths of the first portions 122L, 122S are longer than the lengths of the second portions 123L, 123S in the direction along the corresponding side. Moreover, the overlapping portion 125 has a square shape in plan view. Therefore, the rectangular frame-shaped first sealing portion 21 can be easily configured by the four sheet bodies 121 .

As another method for forming the first sealing portion 21, for example, cutting out a sheet-like base material into a frame shape is conceivable. In this case, the frame-shaped portion cut out from the base material is used as the first sealing portion, while the central portion surrounded by the frame-shaped portion is discarded. In this embodiment, the rectangular frame-shaped first sealing portion 21 is formed by four substantially strip-shaped sheet members. Therefore, the sheet body 121 can be efficiently cut out from the sheet-shaped base material, and the waste amount of the base material can be reduced.

Although the embodiments of the present invention have been described in detail above, the present invention is not limited to the above embodiments. For example, as described below, the first sealing portion 21 may be formed of a sheet body having a shape different from that of the sheet body of the first embodiment.

[Second embodiment]
FIG. 9 is a plan view for explaining an electrode unit according to another example, showing the correspondence relationship between the bipolar electrodes 14 and the sheet body 221. As shown in FIG. FIG. 10 is a plan view for explaining the electrode unit of the example of FIG. 9, showing a state in which the sheet body 221 joined to the bipolar electrodes 14 is unfolded. 11 is a plan view showing the electrode unit 230 in the example of FIG. 9. FIG. Since the manufacturing method is the same as that of the first embodiment, the description is omitted.

The four sheet bodies 221 are composed of two sheet bodies 221L corresponding to the long sides of the bipolar electrode 14 and two sheet bodies 221S corresponding to the short sides. The sheet body 221L includes a first portion 222L and a second portion 223L. The first portion 222L includes a portion joined to the edge 15c of the bipolar electrode 14. As shown in FIG. The second portion 223L is a portion folded back toward the first portion 222L. In the illustrated example, the boundary between the first portion 222L and the second portion 223L is indicated by a chain double-dashed line. The second portion 223L is folded back toward the first portion 222L along the two-dot chain line (folding line 221a).

Both the first portion 222L and the second portion 223L in the illustrated example are trapezoidal. That is, the first portion 222L and the second portion 223L include an upper base and a lower base that form the base, and a pair of legs that connect the upper base and the lower base. In this specification, the longer side of the base is referred to as the lower base. The sheet body 221 has a hexagonal shape in which a side corresponding to the lower base of the trapezoid in the first portion 222L and a side corresponding to the lower base of the trapezoid in the second portion 223L are connected to each other. In the illustrated example, the first portion 222L and the second portion 223L are isosceles trapezoids. The length of the first portion 222L is greater than the length of the second portion 223L in the width direction intersecting the direction of the corresponding side. That is, in the direction along the short side of the bipolar electrode 14, the length L21 of the first portion 222L is longer than the length L22 of the second portion 223L.

The inner angle θ1 between the bottom and the leg in the first portion 222L is larger than 45 degrees. In addition, the sum of the interior angle θ1 formed between the bottom of the first portion 222L and the leg and the interior angle θ2 formed between the bottom of the second portion 223L and the leg is 90 degrees.

The sheet body 221S includes a first portion 222S and a second portion 223S. The first portion 222S includes a portion joined to the edge 15c of the bipolar electrode 14. As shown in FIG. The second portion 223S is a portion folded back toward the first portion 222S. In the illustrated example, the boundary between the first portion 222S and the second portion 223S is indicated by a chain double-dashed line. The second portion 223S is folded back toward the first portion 222S along the two-dot chain line (folding line 221a).

Both the first portion 222S and the second portion 223S are trapezoidal. That is, the first portion 222S and the second portion 223S include an upper base and a lower base that form the base, and a pair of legs that connect the upper base and the lower base. The sheet body 221 has a hexagonal shape in which a side corresponding to the lower base of the trapezoid in the first portion 222S and a side corresponding to the lower base of the trapezoid in the second portion 223S are connected to each other. In the illustrated example, the first portion 222S and the second portion 223S are isosceles trapezoids. The length of the first portion 222S is greater than the length of the second portion 223S in the width direction that intersects the direction along the corresponding side. That is, in the direction along the long side of the bipolar electrode 14, the length L23 of the first portion 222S is longer than the length L24 of the second portion 223S. In this embodiment, the widthwise length L21 of the first portion 222L of the sheet body 221L is the same as the widthwise length L23 of the first portion 222S of the sheet body 221S. Further, the widthwise length L22 of the second portion 223L of the sheet body 221L is the same as the widthwise length L24 of the second portion 223S of the sheet body 221S.

The inner angle θ3 between the bottom and the leg in the first portion 222S is larger than 45 degrees. In addition, the sum of the interior angle θ3 formed between the base and the leg in the first portion 222S and the interior angle θ4 formed between the base and the leg in the second portion 223S is 90 degrees. Also, the interior angle θ3 at the first portion 222S of the sheet body 221S is equal to the interior angle θ1 at the first portion 222L of the sheet body 221L. Therefore, in the illustrated example, the interior angle θ4 at the second portion 223S of the sheet body 221S is also equal to the interior angle θ2 at the second portion 223L of the sheet body 221L.

As shown in FIG. 10, in the present embodiment, a portion of the first portion 222L of the sheet body 221L is joined along the edge 15c of the long side of the bipolar electrode 14. As shown in FIG. The second portion 223L of the sheet body 221L does not overlap the bipolar electrode 14. As shown in FIG. That is, the boundary (folding line 221a) between the first portion 222L and the second portion 223L indicated by a two-dot chain line is positioned outside the bipolar electrode 14. As shown in FIG.

A part of the first portion 222S of the sheet body 221S is joined along the edge 15c of the short side of the bipolar electrode 14. As shown in FIG. The second portion 223S of the sheet body 221S does not overlap the bipolar electrodes 14. As shown in FIG. That is, the boundary (folding line 221a) between the first portion 222S and the second portion 223S indicated by the two-dot chain line is positioned outside the bipolar electrode 14. As shown in FIG.

The sheet body 221L and the sheet body 221S corresponding to adjacent sides of the bipolar electrode 14 form an overlapping portion 125 in which the end of the first portion 222L and the end of the first portion 222S overlap each other. In the illustrated example, the end of the first portion 222S of the sheet body 221S overlaps the end of the first portion 222L of the sheet body 221L. The sheet bodies 221 adjacent to each other are stacked so that the corners including the bottom bases are aligned with each other. Therefore, the overlapping portion 225 has a quadrangular shape including the legs of the first portion 222L of the seat body 221L and the legs of the first portion 222S of the seat body 221S. In FIG. 10, the overlapping portion 225 is shown as an area surrounded by solid and dashed lines.

As shown in FIG. 11, in the electrode unit 230, the second portion 223S of the sheet body 221S is folded back toward the first portion 222S avoiding the overlapping portion 225. As shown in FIG. Similarly, the second portion 223L of the sheet body 221L is folded back toward the first portion 222L avoiding the overlapping portion 225. As shown in FIG. The folded second portion 223S and the second portion 223L may ideally be in contact with the overlapping portion 225, but may be separated from the overlapping portion 225. For example, the leg of the folded second portion 223L may be spaced apart from the leg of the first portion 222S, which is part of the contour of the overlapping portion 225, as shown.

The first sealing portion 21 made up of four sheet bodies 221 has a rectangular frame shape in plan view. The first sealing portion 21 surrounds the edge portion 15c of the electrode plate 15 and is joined to the edge portion 15c. An inner edge 25 s of the first sealing portion 21 is located inside the peripheral edge 15 d of the electrode plate 15 . The first sealing portion 21 is partially formed into two layers by folding back the folding line 221a of the sheet body 221 . That is, the first sealing portion 21 includes a first layer 25 formed by first portions 222L and 222S joined to the bipolar electrode 14, and a second portion 223L folded back toward the first layer 25 side and laminated. and a second layer 27 formed by 223S. The separator 13 can be bonded to the inner peripheral edge portion 25b including the inner edge 25s of the first layer 25 .

In the electrode unit 230 described above, the interior angles θ1 and θ3 formed by the lower base and the legs of the first portions 222L and 222S are larger than 45 degrees. Therefore, when the four sheet members 221 are arranged in a rectangular frame shape, overlapping portions 225 are formed in which the ends of the adjacent sheet members 221 are overlapped with each other. The sum of the interior angle θ1 of the first portion 222L and the interior angle θ2 of the second portion 223L is 90 degrees, and the sum of the interior angle θ3 of the first portion 222S and the interior angle θ4 of the second portion 223S is 90 degrees. When the two portions 223L and 223S are folded back, the second portions 223L and 223S can avoid the overlapping portion 225.例文帳に追加In order for the second portions 223L and 223S to more reliably avoid the overlapping portion 225, the sum of the interior angles should be less than 90 degrees.

[Third embodiment]
FIG. 12 is a plan view for explaining an electrode unit according to still another example, showing the correspondence relationship between the bipolar electrodes 14 and the sheet body 321. As shown in FIG. FIG. 13 is a plan view for explaining the electrode unit in the example of FIG. 12, and shows a state in which the sheet body 321 joined to the bipolar electrodes 14 is unfolded. 14 is a plan view showing the electrode unit 330 of the example of FIG. 12. FIG. Since the manufacturing method is the same as that of the first embodiment, the description is omitted.

The four sheet bodies 321 are composed of two sheet bodies 321L corresponding to the long sides of the bipolar electrode 14 and two sheet bodies 321S corresponding to the short sides. The sheet body 321L includes a first portion 322L and a second portion 323L. The first portion 322L includes a portion joined to the edge 15c of the bipolar electrode 14. As shown in FIG. The second portion 323L is a portion folded back toward the first portion 322L. In the illustrated example, the boundary between the first portion 322L and the second portion 323L is indicated by a chain double-dashed line. The second portion 323L is folded back toward the first portion 322L along the two-dot chain line (folding line 321a).

The first portion 322L has a shape in which a trapezoidal portion and a rectangular portion are connected. In the illustrated example, the boundary between the trapezoidal portion and the rectangular portion is indicated by a dashed line. As illustrated, in the first portion 322L, the lower base of the trapezoidal portion and one of the long sides of the rectangular portion are connected. The trapezoidal portion has an isosceles trapezoidal shape. The second portion 323L has an isosceles trapezoidal shape. In the sheet body 321, the other long side of the rectangular portion of the first portion 322L and the trapezoidal lower base of the second portion 323L are connected to each other. Thereby, the sheet body 321 has an octagonal shape. The length of the first portion 322L is greater than the length of the second portion 323L in the width direction intersecting the direction along the corresponding side. That is, in the direction along the short side of the bipolar electrode 14, the length L31 of the first portion 322L is longer than the length L32 of the second portion 323L.

An interior angle θ31 formed between the bottom of the trapezoidal portion of the first portion 322L and the leg and an interior angle θ32 formed between the bottom of the trapezoidal portion and the leg of the second portion 323L are both 45 degrees.

The sheet body 321S includes a first portion 322S and a second portion 323S. The first portion 322S includes a portion joined to the edge 15c of the bipolar electrode 14. As shown in FIG. The second portion 323S is a portion folded back toward the first portion 322S. In the illustrated example, the boundary between the first portion 322S and the second portion 323S is indicated by a chain double-dashed line. The second portion 323S is folded back toward the first portion 322S along the two-dot chain line (folding line 321a).

The first portion 322S has a shape in which a trapezoidal portion and a rectangular portion are connected. In the illustrated example, the boundary between the trapezoidal portion and the rectangular portion is indicated by a dashed line. As illustrated, in the first portion 322S, the lower base of the trapezoidal portion and one of the long sides of the rectangular portion are connected. The trapezoidal portion has an isosceles trapezoidal shape. The second portion 323S has an isosceles trapezoidal shape. In the sheet body 321, the other long side of the rectangular portion of the first portion 322S and the trapezoidal lower base of the second portion 323S are connected to each other. Thereby, the sheet body 321 has an octagonal shape. The length of the first portion 322S is greater than the length of the second portion 323S in the width direction intersecting the direction along the corresponding side. That is, in the direction along the long side of the bipolar electrode 14, the length L33 of the first portion 322S is longer than the length L34 of the second portion 323S. In this embodiment, the widthwise length L31 of the first portion 322L of the sheet body 321L is the same as the widthwise length L33 of the first portion 322S of the sheet body 321S. Further, the widthwise length L32 of the second portion 323L of the sheet body 321L and the widthwise length L34 of the second portion 323S of the sheet body 321S are the same.

An interior angle θ33 formed between the bottom of the trapezoidal portion of the first portion 322 and the leg and an interior angle θ34 formed between the bottom of the trapezoidal portion and the leg of the second portion 323 are both 45 degrees.

As shown in FIG. 13, in the present embodiment, a portion of the first portion 322L of the sheet body 321L is joined along the edge 15c of the long side of the bipolar electrode 14. As shown in FIG. The second portion 323L of the sheet body 321L does not overlap the bipolar electrode 14. As shown in FIG. That is, the boundary (folding line 321a) between the first portion 322L and the second portion 323L indicated by a two-dot chain line is positioned outside the bipolar electrode 14. As shown in FIG.

A part of the first portion 322S of the sheet body 321S is joined along the edge 15c of the short side of the bipolar electrode 14. As shown in FIG. The second portion 323S of the sheet body 321S does not overlap the bipolar electrode 14. As shown in FIG. That is, the boundary (folding line 321a) between the first portion 322S and the second portion 323S indicated by the two-dot chain line is located outside the bipolar electrode 14. As shown in FIG.

The sheet body 321L and the sheet body 321S corresponding to adjacent sides of the bipolar electrode 14 form an overlapping portion 325 in which the end of the first portion 322L and the end of the first portion 322S overlap each other. In the illustrated example, the midpoint position C1 of the short side of the rectangular portion of the sheet body 321L and the midpoint position C2 of the short side of the rectangular portion of the sheet body 321S overlap. Therefore, the overlapping portion 325 has a hexagonal shape including the trapezoidal leg of the first portion 322L of the sheet body 321L and the trapezoidal leg of the first portion 322S of the sheet body 321S. In FIG. 13, overlap 325 is shown as the area bounded by solid and dashed lines.

As shown in FIG. 14, in the electrode unit 330, the second portion 323S of the sheet body 321S is folded back toward the first portion 322S avoiding the overlapping portion 325. As shown in FIG. Similarly, the second portion 323L of the sheet body 321L is folded back toward the first portion 322L avoiding the overlapping portion 325. As shown in FIG. The folded second portion 323S and the second portion 323L may ideally be in contact with the overlapping portion 325, but may be separated from the overlapping portion 325. For example, in the illustrated example, the legs of the folded second portion 323L and the legs of the trapezoidal portion of the first portion 322S may be separated from each other.

The first sealing portion 21 made up of four sheet members 321 has a substantially rectangular frame shape in plan view. The first sealing portion 21 surrounds the edge portion 15c of the electrode plate 15 and is joined to the edge portion 15c. An inner edge 25 s of the first sealing portion 21 is located inside the peripheral edge 15 d of the electrode plate 15 . The first sealing portion 21 is partially formed into two layers by folding back the folding line 321 a at a position outside the peripheral edge 15 d of the electrode plate 15 . That is, the first sealing portion 21 includes a first layer 25 formed by first portions 322L and 322S joined to the bipolar electrode 14, a second portion 323L folded back toward the first layer 25, and a second portion 323L. and a second layer 27 formed by 323S. The separator 13 can be bonded to the inner peripheral edge portion 25b including the inner edge 25s of the first layer 25 .

In the sheet body 321 described above, the interior angles θ31 and θ33 formed between the lower base and the legs of the trapezoidal portions of the first portions 322L and 322S, and the inner angles θ32 and θ34 formed between the lower base and the legs of the second portions 323L and 323S. are all 45 degrees. In this configuration, the legs of the folded second portions 323L, 323S and the legs of the adjacent first portions 322S, 322L of the seat body 321 are parallel. To easily control the positional relationship between the legs of the folded second portions 323L, 323S and the legs of the first portions 322S, 322L of the adjacent sheet bodies 321 by adjusting the positions of the adjacent sheet bodies 321. - 特許庁can be done. In the above embodiment, the position C1 of the midpoint of the short side of the rectangular portion of the sheet body 321L and the position C2 of the midpoint of the short side of the rectangular portion of the sheet body 321S overlap. In this configuration, the positions of the legs of the folded second portions 323L, 323S and the positions of the legs of the adjacent first portions 322S, 322L of the seat body 321 can match.

[Fourth embodiment]
FIG. 15 is a plan view for explaining an electrode unit according to another example, showing the correspondence relationship between the bipolar electrodes 14 and the sheet body 421. As shown in FIG. FIG. 16 is a plan view for explaining the electrode unit in the example of FIG. 15, showing a state in which the sheet body 421 joined to the bipolar electrodes 14 is unfolded. 17 is a plan view showing the electrode unit 430 of the example of FIG. 15. FIG.

The four sheet bodies 421 are composed of two sheet bodies 421L corresponding to the long sides of the bipolar electrode 14 and two sheet bodies 421S corresponding to the short sides. The sheet body 421L includes a first portion 422L and a second portion 423L. The first portion 422L includes a portion joined to the edge 15c of the bipolar electrode 14. As shown in FIG. The second portion 423L is a portion folded back toward the first portion 422L. In the illustrated example, the boundary between the first portion 422L and the second portion 423L is indicated by a chain double-dashed line. The second portion 423L is folded back toward the first portion 422L along the two-dot chain line (folding line 421a).

The sheet body 421L has a hexagonal shape in which the sides corresponding to the lower bases of two trapezoids are connected to each other. In the illustrated example, the boundary between two trapezoids is indicated by a dashed line. Both of the two trapezoidal portions of the seat body 421L are isosceles trapezoids having internal angles θ41 and θ42 formed by the bottom and the legs of 45°.

The first portion 422L completely includes one trapezoidal portion of the sheet body 421L and includes part of the other trapezoidal portion. That is, the first portion 422L has a hexagonal shape in which the sides corresponding to the lower bases of the two trapezoids are connected to each other. The second portion 423L is part of the other trapezoidal portion of the sheet body 421L and has a trapezoidal shape. The length of the first portion 422L is greater than the length of the second portion 423L in the width direction intersecting the direction of the corresponding side. That is, in the direction along the short side of the bipolar electrode 14, the length L41 of the first portion 422L is longer than the length L42 of the second portion 423L.

The sheet body 421S includes a first portion 422S and a second portion 423S. The first portion 422S includes a portion joined to the edge 15c of the bipolar electrode 14. As shown in FIG. The second portion 423S is a portion folded back toward the first portion 422S. In the illustrated example, the boundary between the first portion 422S and the second portion 423S is indicated by a chain double-dashed line. The second portion 423S is folded back toward the first portion 422S along the two-dot chain line (folding line 421a).

The sheet body 421S has a hexagonal shape in which the sides corresponding to the lower bases of two trapezoids are connected to each other. In the illustrated example, the boundary between two trapezoids is indicated by a dashed line. Both of the two trapezoidal portions of the sheet body 421S are isosceles trapezoids in which the inner angles θ43 and θ44 between the bottom and the legs are 45°.

The first portion 422S completely includes one trapezoidal portion of the sheet body 421S and includes part of the other trapezoidal portion. That is, the first portion 422S has a hexagonal shape in which the sides corresponding to the lower bases of the two trapezoids are connected to each other. The second portion 423S is part of the other trapezoidal portion of the sheet body 421S and has a trapezoidal shape. The length of the first portion 422S is greater than the length of the second portion 423S in the width direction intersecting the direction of the corresponding side. That is, in the direction along the long side of the bipolar electrode 14, the length L43 of the first portion 422S is longer than the length L44 of the second portion 423S.

In this embodiment, the widthwise length L41 of the first portion 422L of the sheet body 421L is the same as the widthwise length L43 of the first portion 422S of the sheet body 421S. Further, the widthwise length L42 of the second portion 423L of the sheet body 421L and the widthwise length L44 of the second portion 423S of the sheet body 421S are the same.

As shown in FIG. 16, in the present embodiment, a portion of the first portion 422L of the sheet body 421L is joined along the edge 15c of the long side of the bipolar electrode 14. As shown in FIG. The second portion 423L of the sheet body 421L does not overlap the bipolar electrode 14. As shown in FIG. That is, the boundary (folding line 421a) between the first portion 422L and the second portion 423L indicated by a two-dot chain line is located outside the bipolar electrode 14. As shown in FIG.

A part of the first portion 422S of the sheet body 421S is joined along the edge 15c of the short side of the bipolar electrode 14. As shown in FIG. The second portion 423S of the sheet body 421S does not overlap the bipolar electrode 14. As shown in FIG. That is, the boundary (folding line 421a) between the first portion 422S and the second portion 423S indicated by the two-dot chain line is positioned outside the bipolar electrode 14. As shown in FIG.

The sheet body 421L and the sheet body 421S corresponding to adjacent sides of the bipolar electrode 14 form an overlapping portion 425 in which the end portion of the first portion 422L and the end portion of the first portion 422S overlap each other. In the illustrated example, the end of the first portion 422S of the sheet body 421S overlaps the end of the first portion 422L of the sheet body 421L. Adjacent sheet bodies 421 are stacked on each other such that the legs of the second portion 423L and the legs of the second portion 423S are arranged in a straight line. Therefore, the overlapping portion 425 has a quadrangular shape including the inner trapezoidal leg of the first portion 422L of the seat body 421L and the inner trapezoidal leg of the first portion 422S of the seat body 421S. In FIG. 16, the overlapping portion 425 is shown as an area surrounded by solid and dashed lines.

As shown in FIG. 17, in the electrode unit 430, the second portion 423S of the sheet body 421S is folded back toward the first portion 422S avoiding the overlapping portion 425. As shown in FIG. Similarly, the second portion 423L of the sheet body 421L is folded back toward the first portion 422L avoiding the overlapping portion 425. As shown in FIG. The folded second portion 423S and the second portion 423L may ideally be in contact with the overlapping portion 425, but may be separated from the overlapping portion 425. For example, in the illustrated example, the legs of the folded second portion 423L may be spaced apart from the inner trapezoidal legs of the first portion 422S that are part of the contour of the overlap 425. FIG.

The first sealing portion 21 made up of four sheet members 421 has a rectangular frame shape in plan view. The first sealing portion 21 surrounds the edge portion 15c of the electrode plate 15 and is joined to the edge portion 15c. An inner edge 25 s of the first sealing portion 21 is located inside the peripheral edge 15 d of the electrode plate 15 . The first sealing portion 21 is partially formed into two layers by folding back the folding line 421a of the sheet body 421 . That is, the first sealing portion 21 includes a first layer 25 formed by first portions 422L and 422S joined to the bipolar electrode 14, a second portion 423L folded back toward the first layer 25, and a second portion 423L. and a second layer 27 formed by 423S. The separator 13 can be bonded to the inner peripheral edge portion 25b including the inner edge 25s of the first layer 25 .

In the electrode unit 430 described above, the leg of the second portion 423L and the leg of the second portion 423S are arranged on a straight line between the sheet bodies 421 adjacent to each other. In one example, as shown in FIG. 15, the electrode unit 430 can be manufactured by preparing a sheet body 421 having a shape in which two trapezoids are connected. Also, the electrode unit 430 may be manufactured using a sheet body having another shape. FIG. 18 is a diagram for explaining another example of the manufacturing process of the electrode unit. In manufacturing the electrode unit 430, as shown in FIG. 18, trapezoidal sheet bodies 429S and 429L may be prepared. The sheet bodies 429S and 429L have an isosceles trapezoidal shape. The internal angle θ45 between the bottom and the leg is 45°. For example, after joining the four sheet bodies 429S and 429L to the bipolar electrode 14, the adjacent sheet bodies 429S and 429L are cut along the direction orthogonal to the legs. The cut locations indicated by the dash-dot lines form the legs of the second portion 423L and the legs of the second portion 423S. As a result, the sheet bodies 429S and 429L have the same shape as the sheet bodies 421S and 421L.

14 Bipolar electrode 15c Edge 21 First sealing portion (sealing body) 30 Electrode unit 121, 121L, 121S Sheet body 122L, 122S First portion 123L, 123S Second 2 parts, 125...overlapping part.

Claims (8)

An electrode unit comprising a rectangular bipolar electrode and a frame-shaped sealing member joined to an edge of the bipolar electrode,
The sealing body is composed of a plurality of sheet bodies arranged corresponding to each side of the rectangle formed by the bipolar electrodes,
The sheet body includes a first portion including a portion joined to the bipolar electrode and a second portion folded back toward the first portion,
In the sheet bodies arranged adjacent to each other, overlapping portions are formed in which the ends of the first portions overlap with each other,
the second portion is folded back to the first portion avoiding the overlapping portion;
The electrode unit, wherein the length of the first portion is greater than the length of the second portion in a width direction that intersects the direction of the corresponding side. 2. The electrode unit according to claim 1, wherein the folding line for folding the second portion is positioned outside the outer edge of the bipolar electrode. Both the first portion and the second portion are rectangular,
3. The electrode unit according to claim 1 or 2, wherein the length of the first portion is greater than the length of the second portion in the direction of the corresponding side. 4. The electrode unit according to claim 3, wherein the overlapping portion has a square shape in plan view. In the sheet body, a lower base of the first portion having a trapezoidal shape and a lower base of the second portion having a trapezoidal shape are connected to each other,
an internal angle between the bottom and the leg in the first portion is greater than 45 degrees;
3. The electrode unit according to claim 1 or 2, wherein the sum of the internal angle between the base and the leg in the first portion and the internal angle between the base and the leg in the second portion is 90 degrees. The sheet body has a first portion in which the lower base of the trapezoidal portion and one long side of the rectangular portion are connected to each other, and a lower base in the first portion that is connected to the other long side of the rectangular portion. a trapezoidal second portion;
3. The interior angle between the lower base and the legs of the trapezoidal portion in the first portion and the inner angle between the lower base and the legs in the second portion are both 45 degrees, according to claim 1 or 2. electrode unit. Between the sheet bodies corresponding to adjacent sides, the position of the midpoint of the short side of the rectangular portion of one sheet body and the midpoint of the short side of the rectangular portion of the other sheet body are 7. The electrode unit according to claim 6, overlapping. A method for manufacturing an electrode unit,
arranging a plurality of sheet bodies corresponding to each side of a rectangular bipolar electrode on each corresponding side; joining the arranged sheet bodies to the bipolar electrodes;
A step of folding back a second portion formed continuously with the first portion toward a first portion including a portion to be joined to the bipolar electrode of the joined sheet body,
In the arranging step, ends of the first portions of the sheet bodies corresponding to adjacent sides are overlapped to form overlapping portions,
In the folding step, the second portion is folded back to the first portion while avoiding the overlapping portion, and the edge portion of the second portion overlaps the edge of the first portion in a width direction that intersects the direction of the corresponding side. A method of manufacturing an electrode unit, wherein the second portion is folded back so as to be positioned inside the sheet body relative to the portion.

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