JP2015002264A - Power storage module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power storage module which facilities assembly work thereof.SOLUTION: A power storage module 1 includes a plurality of power storage cells 2 which are formed by tightly sealing an electrode laminate obtained by laminating a positive electrode and a negative electrode, and an organic electrolyte, into a container 11 formed of an aluminum laminate film material and encapsulating them therein. In the power storage module 1, main surfaces are overlapped on each other in a state where a pressure-sensitive adhesive is coated on the cell main surface of each power storage cell 2, and the power storage cells 2 are adhered to each other in a state where the respective cell main surfaces are pressed in the overlapping direction.

Description

  The present invention relates to a power storage module.

  In recent years, there are power storage devices applied to power storage systems. As an example of the electricity storage device, a lithium ion capacitor has been proposed. An energy storage cell of a lithium ion capacitor includes, for example, an electrode laminate in which positive electrodes, negative electrodes, and separators are alternately laminated in a container of an airtight packaging material such as an aluminum laminate film, and an organic electrolyte solution containing, for example, lithium ions. It is a sealed structure filled.

  In a power storage system, a power storage module has been proposed in which a plurality of power storage cells are stacked and connected in series or in parallel. In addition, in some power storage modules, a plurality of power storage cells stacked between end plates are pressed and held in the stacking direction using an upper end plate and a lower end plate.

JP 2010-161044 A

  However, the power storage module has a problem that assembly work is not easy. For example, when assembling a power storage module, it is necessary to align the terminals of the power storage cells in order to electrically connect the power storage cells in series or in parallel, instead of simply arranging or stacking the power storage cells. Here, if a plurality of power storage cells are attached to each other with a double-sided tape, they are bonded with a double-sided tape before aligning the terminals of the power storage cells. And since the electrical storage cell is being fixed with the double-sided tape, the fine adjustment while moving the electrical storage cell is also difficult. Thus, the assembly operation of the power storage module is not easy.

  In view of the above-described problems, an example of an embodiment of the disclosed technology aims to provide a power storage module that can be easily assembled.

  A power storage module according to an example of an embodiment of the disclosed technology includes a plurality of power storage cells in which an electrode laminate in which a positive electrode and a negative electrode are stacked is sealed in a container of a laminate material. The power storage module is characterized in that the storage cells are bonded to each other in a state where the flat surfaces are overlaid in a state where the pressure curable adhesive is applied to the flat surfaces of the respective storage cells and each flat surface is pressed in the overlapping direction. And

  According to an example of an embodiment of the disclosed technology, an electricity storage module that can be easily assembled can be provided.

FIG. 1 is a perspective view illustrating an example of the power storage module of the embodiment. FIG. 2 is a side view showing an example of the power storage module. FIG. 3 is a perspective view showing an example of a storage cell. FIG. 4 is an explanatory diagram illustrating an example of a storage cell. FIG. 5 is a perspective view showing an example of the first end plate. FIG. 6 is a side view showing an example of the assembly process of the power storage module. FIG. 7 is a perspective view illustrating an example of an assembly process of the power storage module. FIG. 8 is a flowchart showing an example of the power storage module assembly process.

  Hereinafter, a power storage module according to an example of an embodiment of the disclosed technology will be described with reference to the drawings. The following embodiments are merely examples, and do not limit the disclosed technology. Further, the following embodiments can be appropriately combined within a consistent range. Further, in the embodiment, the same reference numerals are given to the same components, and the description thereof will be omitted in the later case.

[Embodiment]
(Configuration of power storage module according to the embodiment)
FIG. 1 is a perspective view illustrating an example of the power storage module according to the embodiment, and FIG. 2 is a side view illustrating an example of the power storage module. The power storage module 1 shown in FIG. 1 includes a plurality of power storage cells 2, a first end plate 3A, a second end plate 3B, and a bracket 4. The power storage module 1 is, for example, a lithium ion capacitor module.

  As will be described later, the power storage module 1 according to the embodiment includes a plurality of power storage cells 2 in which an electrode laminate in which a positive electrode and a negative electrode are stacked is sealed in a container of a laminate material. In the storage module 1, the planes are overlaid in a state where a pressure curable adhesive (pressure-sensitive adhesive) is applied to the plane (cell main surface) of each storage cell 2, and each plane is pressed in the stacking direction. In this state, the storage cells 2 are bonded together. The pressure-curable adhesive used here is cured when a predetermined pressure is reached and exhibits a predetermined grip force. For this reason, even when the cell main surfaces of the electricity storage cell 2 are overlapped, the gripping force is not exhibited in a state where the cell main surfaces are not pressurized with a predetermined pressure. The terminals of the cell 2 can be aligned. On the other hand, since the grip force is exerted in a state where the predetermined pressure is applied, the state where the terminals of the storage cell 2 are aligned can be maintained. Thus, the electrical storage module 1 with easy assembly work can be provided. In addition, although the electrical storage module 1 of this embodiment showed the electrical storage module which mounted 12 electrical storage cells 2 as an example, for example, it is not limited to 12 sheets and what number may be sufficient.

  FIG. 3 is a perspective view illustrating an example of the storage cell 2, and FIG. 4 is an explanatory diagram illustrating an example of the storage cell 2. The electrical storage cell 2 shown in FIG. 3 is a lithium ion capacitor cell, for example. The storage cell 2 includes a container 11 that houses an electrode stack (not shown) and an electrode terminal 12. The electrode laminate is configured by laminating a positive electrode, a negative electrode, and a separator (not shown). The power generation element is one unit, and a plurality of units of power generation elements are stacked.

  The positive electrode has, for example, a structure in which a positive electrode made of a material capable of reversibly supporting lithium ions is formed on a positive electrode current collector. The positive electrode current collector is a member for collecting current while supporting the positive electrode, and is formed using, for example, a conductive metal plate such as aluminum. The positive electrode current collector is formed in a rectangular shape in plan view and has a structure in which the tab 14A protrudes from one of the four sides. The tab 14A is connected to the positive electrode terminal 12A such as aluminum among the electrode terminals 12.

  The negative electrode has, for example, a structure in which a negative electrode made of a material capable of reversibly supporting lithium ions is formed on a negative electrode current collector. The negative electrode current collector is a member for collecting current while supporting the negative electrode, and is formed using a conductive metal plate such as copper, for example. The negative electrode current collector is formed in a rectangular shape in plan view, and has a structure in which the tab 14B protrudes from one of the four sides. The tab 14 </ b> B is connected to the negative electrode terminal 12 </ b> B such as copper among the electrode terminals 12. Moreover, the negative electrode current collector has a lithium sticking portion (not shown) to which a pre-doping lithium metal foil is stuck. The lithium metal foil dissolves and disappears when pre-doping is completed.

  The container 11 is, for example, a rectangular soft container made of an aluminum laminated film material obtained by laminating an aluminum foil with a resin film. Furthermore, the container 11 has a structure in which the electrode stack is sealed together with an organic electrolyte containing lithium ions, for example. Since the container 11 seals the electrode laminate and the organic electrolyte, the surface portion of the container 11 has a shape in which the shape of the electrode laminate is raised near the center. The raised surface portion of the container 11 is referred to as a cell main surface 13. In addition, as a layer structure of the aluminum laminate film material, PP (Polypropylene) layer, PPa (polyphthalamide) layer, AL (aluminum) layer, nylon layer, PET (from the inner layer to the outer layer of the storage cell 2 PolyEthyleneTerephthalate) layer. The layer structure of the aluminum laminate film material may be, for example, a PPa (polyphthalamide) layer, an AL (aluminum) layer, a nylon layer, and a PET (PolyEthylene Terephthalate) layer.

The pressure sensitive adhesive 5 is a pressure curable adhesive that cures according to a predetermined pressure, for example, a pressure of 0.25 ± 0.05 (Kgf / cm ² ). Further, the cured adhesive can suppress slipping by exhibiting a predetermined grip force. In addition, the power storage cell 2 is configured such that the cell main surface 13 and the flat surface 31 of the first end plate 3 </ b> A are overlapped and bonded with the pressure-sensitive adhesive 5.

  When the electrode stack is accommodated in the container 11, the storage cell 2 has a structure in which the positive electrode terminal 12 </ b> A and the negative electrode terminal 12 </ b> B protrude from one side of the four rectangular sides. The positive electrode terminal 12A is made of, for example, an aluminum material, and has a structure in which a tip portion thereof is bent at a right angle toward one cell main surface 13 as shown in FIGS. 3 and 4C. The negative electrode terminal 12B is made of, for example, a copper material, and has a structure in which a tip portion thereof is bent at a right angle toward the other cell main surface 13 as shown in FIGS. 3 and 4C.

  In the power storage module 1, for example, when a plurality of power storage cells 2 are connected in series, the front end portion of the positive electrode terminal 12 </ b> A of the power storage cell 2 and the front end of the negative electrode terminal 12 </ b> B of the opposite power storage cell 2 in surface contact with the power storage cell 2. The part is electrically connected by welding or the like. Further, in the power storage module 1, the tip portion of the negative electrode terminal 12B of the power storage cell 2 and the tip portion of the positive electrode terminal 12A of the power storage cell 2 on the opposite side are electrically connected by welding or the like.

  In addition, for example, in the case where a plurality of power storage cells 2 are connected in parallel, the power storage module 1 includes the tip of the positive electrode terminal 12A of the power storage cell 2 and the positive electrode terminal 12A of the opposite power storage cell 2 in surface contact with the power storage cell 2. The tip part is electrically connected by welding or the like. Furthermore, the power storage module 1 electrically connects the tip portion of the negative electrode terminal 12B of the power storage cell 2 and the tip portion of the negative electrode terminal 12B of the opposite power storage cell 2 by welding or the like.

  As shown in FIG. 3 and FIG. 4 (A), guide grooves 15A and 15B penetrating the terminal main body on the front and back are formed in the positive electrode terminal 12A and the negative electrode terminal 12B of the storage cell 2, respectively. Note that, for example, two positioning pins 61A and 61B of the storage cell 2 are arranged on the work table used in the storage module assembling step. The distance P1 between the positioning pin 61A and the positioning pin 61B is the same as the distance P2 between the guide groove 15A on the positive electrode terminal 12A side of the storage cell 2 and the guide groove 15B on the negative electrode terminal 12B side. Therefore, the positioning pins 61A and 61B are inserted into the guide groove 15A on the positive electrode terminal 12A side and the guide groove 15B on the negative electrode terminal 12B side of the storage cell 2, respectively, so that the plurality of storage cells 2 can be overlapped while positioning. it can.

  FIG. 5 is a perspective view showing an example of the first end plate 3A. The first end plate 3A shown in FIG. 5 is formed of a sheet metal member having a rectangular shape in plan view, and includes a flat surface 31 and a frame portion 32. The flat surface 31 is a surface portion that is in surface contact with the cell main surface 13 of the electricity storage cell 2. The frame portion 32 is formed on the short side of the first end plate 3 </ b> A so as to extend in a direction orthogonal to the flat surface 31. Further, the flat surface 31 is in surface contact with the cell main surface 13 of the electricity storage cell 2 arranged at the lowest part in the stacking direction of the electricity storage cells 2. The second end plate 3B has the same configuration as that of the first end plate 3A shown in FIG. 4, and therefore, the same reference numerals are given and description of the overlapping configuration and operation is omitted. The flat surface 31 of the second end plate 3 </ b> B is in surface contact with the cell main surface 13 of the electricity storage cell 2 disposed at the uppermost portion in the stacking direction of the electricity storage cells 2.

  The bracket 4 shown in FIG. 1 has two brackets having a substantially U-shaped cross section, a first bracket 4A for holding a cell assembly to be described later from one side surface on the short side, and a short cell assembly. And a second bracket 4B held from the other side of the hand side. The cell aggregate is an aggregate in which the first end plate 3A, the plurality of power storage cells 2 and the second end plate 3B are overlapped. The first bracket 4A is sandwiched and held between the surface of the flat surface 31 of the first end plate 3A and the surface of the flat surface 31 of the second end plate 3B in the cell assembly. The second bracket 4B sandwiches and holds the surface of the flat surface 31 of the first end plate 3A and the surface of the flat surface 31 of the second end plate 3B in the cell assembly.

  The flat surface 31 of the second end plate 3B is provided with a screw hole (not shown) at a portion that contacts the end surface of the first bracket 4A, and the adjustment screw 51 is screwed into the screw hole so that the tip of the adjustment screw 51 The portion presses the end surface of the first bracket 4A. Accordingly, in the second end plate 3B, the first bracket 4A moves to the first end plate 3A side in accordance with the pressing of the tip portion of the adjustment screw 51, and pressurizes the cell aggregate.

  The flat surface 31 of the second end plate 3B is provided with a screw hole (not shown) in a portion that contacts the end surface of the second bracket 4B, and the adjustment screw 51 is screwed into the screw hole so that the tip of the adjustment screw 51 The portion presses the end surface of the second bracket 4B. Accordingly, in the second end plate 3B, the second bracket 4B moves to the first end plate 3A side in accordance with the pressing of the tip portion of the adjustment screw 51, and pressurizes the cell assembly.

  The first bracket 4A and the second bracket 4B pressurize the cell assembly from both sides using the first end plate 3A and the second end plate 3B. Thereby, the pressure-sensitive adhesive 5 applied to the cell main surface 13 and the flat surface 31 in the cell assembly is cured. And grip power increases by hardening of the pressure sensitive adhesive 5 between the cell main surfaces 13 of the electrical storage cell 2 or between the cell main surface 13 and the flat surface 31.

(Assembly method of power storage module according to embodiment)
Next, a method for assembling the power storage module 1 of this embodiment will be described. 6 is a side view showing an example of the assembly process of the power storage module, FIG. 7 is a perspective view showing an example of the assembly process of the power storage module 1, and FIG. 8 is a flowchart showing an example of the assembly process of the power storage module 1. is there. As shown in FIGS. 6 and 7, the worker places the first end plate 3A on the work table in consideration of the positions of the positioning pins 61A and 61B on the work table (step S11). The worker applies the pressure-sensitive adhesive 5 to the cell main surface 13 of the storage cell 2 to be mounted (step S12). As a method for applying the pressure sensitive adhesive 5, for example, spray coating or spiral coating may be used. Alternatively, a film containing the pressure-sensitive adhesive 5 may be placed on the cell main surface 13 or the flat surface 31 to be replaced with coating. In the example shown in FIG. 7, the pressure-sensitive adhesive 5 is applied to the entire cell main surface 13 of the electricity storage cell 2, but is not limited to the entire cell main surface 13, and may be a part.

  As shown in FIGS. 6 and 7, the operator inserts the guide pins 15 </ b> A and 15 </ b> B of the storage cell 2 into the positioning pins 61 </ b> A and 61 </ b> B on the workbench so that the cell of the storage cell 2 is inserted. The storage cell 2 is mounted so that the main surface 13 is in surface contact with the cell main surface 13 of the other storage cell 2 or the flat surface 31 of the first end plate 3A (step S13). The operator determines whether or not the mounting of all the storage cells 2 has been completed (step S14). In addition, since the power storage module 1 of the present embodiment has a structure in which, for example, 12 power storage cells 2 are mounted, it is determined whether or not the mounting of all the power storage cells 2 has been completed using 12 power storage cells 2. Judgment is made by whether or not it is installed.

  If the mounting of all the storage cells 2 has not been completed (No at Step S14), the worker proceeds to Step S12 to mount a new storage cell 2. In addition, when the mounting of all the energy storage cells 2 is completed (Yes at Step S14), the operator faces the flat surface 31 of the second end plate 3B on the cell main surface 13 of the uppermost energy storage cell 2 in the overlapping direction. The second end plate 3B is mounted so as to come into contact (step S15). In addition, the process of step S11-S15 is a mounting process. The operator completes the cell assembly by sequentially superposing the first end plate 3A, the twelve storage cells 2 and the second end plate 3B through the process of step S15.

  The operator connects the first end plate 3A and the second end plate 3B with the bracket 4 (step S16). At the time when the bracket 4 is connected, the pressure-sensitive adhesive 5 applied to the cell main surface 13 and the flat surface 31 in the cell assembly is not pressurized, so that its adhesiveness is low and the storage cell The position of 2 can be adjusted.

The operator moves the bracket 4 and the second end plate 3B toward the first end plate 3A in accordance with the screw adjustment of the second end plate 3B, and pressurizes the cell assembly (step S17). The pressure on the second end plate 3B side of the bracket 4 is, for example, 0.25 ± 0.05 (Kgf / cm ² ). Thereby, the pressure sensitive adhesive 5 is cured in response to the pressure applied to the pressure sensitive adhesive 5 applied to the cell main surface 13 and the flat surface 31 in the cell assembly (step S18). And the electrical storage module 1 fixes the some electrical storage cell 2 piled up between the 1st end plate 3A and the 2nd end plate 3B with the grip force by hardening of the pressure sensitive adhesive 5. FIG. In addition, the process of step S16-S18 is a pressurization process.

  And an operator performs the terminal connection operation | work which electrically connects the positive electrode terminal 12A and negative electrode terminal 12B of the adjacent electrical storage cell 2 by welding (step S19), and complete | finishes the assembly process shown in FIG. In the case of series connection of the storage cells 2, the worker connects the positive electrode terminal 12A of the storage cell 2 and the negative electrode terminal 12B of the opposite storage cell 2, and stores the negative electrode terminal 12B of the storage cell 2 and the opposite storage power. The positive terminal 12A of the cell 2 is connected. In the case of parallel connection of the storage cells 2, the worker connects the positive electrode terminal 12 </ b> A of the storage cell 2 and the positive electrode terminal 12 </ b> A of the opposite storage cell 2, and stores the storage electrode 2 </ b> B opposite to the negative electrode terminal 12 </ b> B of the storage cell 2. The negative electrode terminal 12B of the cell 2 is connected. Thereby, the electrical storage module 1 is completed.

(Effect by embodiment)
The power storage module 1 of the embodiment has a plurality of power storage cells 2, and the cell main surfaces 13 are overlapped with each other in a state where the pressure sensitive adhesive 5 is applied to the cell main surface 13 of the container 11 of each power storage cell 2. The storage cells 2 are bonded together in a state where each cell main surface 13 is pressed in the overlapping direction. Thereby, the electrical storage module 1 with easy assembly work can be provided. Furthermore, in the manufacturing process, the pressure sensitive adhesive 5 applied to the cell main surface 13 can be finely adjusted before the pressure sensitive adhesive 5 applied to the cell main surface 13 and the storage cells 2 can be rearranged. Compared to the case, the work load can be greatly reduced.

  In the power storage module 1 of the embodiment, the second end plate 3B moves to the first end plate 3A side in accordance with the screw adjustment of the bracket 4 that connects the first end plate 3A and the second end plate 3B. Then, the cell assembly is pressurized. Thereby, the electrical storage module 1 with easy assembly work can be provided. Furthermore, in the manufacturing process, before pressurizing the pressure sensitive adhesive 5 applied to the cell main surface 13 or the flat surface 31 of the cell assembly, the storage cell 2, the first end plate 3A, or the second end plate 3B. Can be finely adjusted and the storage cells 2 can be rearranged. Compared with the use of adhesive tape, the work burden can be greatly reduced.

In the power storage module 1 of the embodiment, the cell main surface is obtained by applying a pressure of 0.20 to 0.30 (Kgf / cm ² ) to the pressure-sensitive adhesive 5 applied to the cell main surface 13 or the flat surface 31. The pressure sensitive adhesive 5 between 13 and between the cell main surface 13 and the flat surface 31 was cured and adhered. Thereby, a grip force is generated between the cell main surfaces 13 or between the cell main surface 13 and the flat surface 31 according to the curing of the pressure-sensitive adhesive 5.

  In the power storage module 1, since the plurality of power storage cells 2 can be positioned and overlapped by the positioning pins 61 </ b> A and 61 </ b> B and the guide grooves 15 </ b> A and 15 </ b> B when the power storage cells 2 are overlapped, the stacking work process is improved. it can. In addition, the pressure sensitive adhesive 5 applied to the cell main surface 13 of the electricity storage cell 2 and the flat surface 31 of each end plate 3 is low in pressure until pressure is applied in the overlapping direction, and the electricity storage cell 2 in the cell assembly is low. The arrangement position of the end plate 3 can be adjusted. Thereby, in the electrical storage module 1, while ensuring the impact resistance and vibration resistance when the electrical storage cells 2 and the end plates 3 are overlapped, the electrical storage cells 2 and the end plates 3 are applied until pressure in the stacking direction is applied to the cell assembly. Can be prevented from being displaced.

(Other variations of the embodiment)
The power storage cell 2 used in the power storage module 1 of the above embodiment has a structure in which the positive electrode terminal 12A and the negative electrode terminal 12B are drawn out in the same direction from one side of the rectangular shape. The structure may be drawn from two sides that intersect at right angles.

  The power storage module 1 of the above embodiment is exemplified by the power storage cell 2 of a lithium pre-doped type lithium ion capacitor, but can be applied to a power storage cell of a type of alkali metal ion capacitor that is pre-doped with an alkali metal other than lithium. is there. Moreover, it is applicable also to electrical storage modules, such as a nonaqueous secondary battery and the electrical storage layer of an electrical double layer capacitor.

  In the said embodiment, although the container 11 of the electrical storage cell 2 was formed with aluminum foil, such as an aluminum laminate film material, you may form with metal laminate film materials of metal foil other than aluminum foil.

  In the above embodiment, the cell main surface 13 is PET, but may be nylon, PP (Polypropylene), or the like.

  In the above embodiment, the cell end assembly is pressurized by moving the second end plate 3B toward the first end plate 3A using the first end plate 3A, the second end plate 3B, the bracket 4, and the like. However, it is not limited to such an embodiment. For example, by winding a plurality of storage cells 2 between the flat surface 31 on the first end plate 3A side and the flat surface 31 on the second end plate 3B side with a belt so as to be sandwiched in the overlapping direction, The power storage cell 2 may be pressurized.

  In the above embodiment, the first end plate 3A and the second end plate 3B are formed of a metal member. However, for example, the first end plate 3A and the second end plate 3B may be formed of a flame retardant resin material such as flame retardant polypropylene or glass-filled nylon. .

DESCRIPTION OF SYMBOLS 1 Power storage module 2 Power storage cell 3A 1st end plate 3B 2nd end plate 4 Bracket 4A 1st bracket 4B 2nd bracket 5 Pressure sensitive adhesive 11 Container 13 Cell main surface 31 Flat surface 51 Adjustment screw

Claims (4)

It has a plurality of storage cells in which an electrode laminate in which a positive electrode and a negative electrode are laminated is sealed in a container of a laminate material,
A power storage module characterized in that the flat surfaces are overlaid in a state where a pressure curable adhesive is applied to the flat surface of each power storage cell, and the power storage cells are bonded together in a state where each flat surface is pressed in the overlapping direction. . A first plate facing the plane of the storage cell disposed on one end side in the overlapping direction;
A second plate facing the plane of the storage cell disposed on the other end side in the overlapping direction;
A pressurizing member that connects the first plate and the second plate and pressurizes the plurality of power storage cells in the stacking direction using the first plate and the second plate. The power storage module according to claim 1.   The pressure curable adhesive is applied to the first plate or the plane of the storage cell facing the first plate and the plane of the storage cell facing the second plate or the second plate. The first plate and the plane opposite to the second plate are bonded in a state where the plurality of storage cells are pressed in the overlapping direction by the pressing member. Item 3. The power storage module according to Item 2. 4. The power storage module according to claim 1, wherein the pressure applied in the overlapping direction is a pressure of 0.20 to 0.30 (Kgf / cm ² ).

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