JP2014022239A - Battery pack - Google Patents

Abstract

PROBLEM TO BE SOLVED: To effectively prevent the electrode tabs of laminated unit cells from being damaged by vibration while the electrode tabs are being connected by bus bars.SOLUTION: A battery pack comprises: a prismatic cell laminate 9 composed of a plurality of plate-like unit cells 1 which are laminated one on top of another, each having a cathode electrode tab 3A and an anode electrode tab 3B; bus bars 5 connected to the electrode tabs 3 of the unit cells 1 constituting the cell laminate 9 and thereby connecting the unit cells 1 together; and an electrode insulation separator 6 disposed between the bus bars 5 connected to each of the opposed electrode tabs 3 of the laminated unit cells 1 and insulating the bus bars 5 having a voltage difference from each other. The electrode insulation separator 6 has an exposed surface 6X exposed to the outer peripheral faces of the cell laminate 9, and a connecting bar 10 extending in the laminated direction of the unit cells 1 is connected to the exposed surface 6X of each electrode insulation separator 6, so that the electrode insulation separators 6 arranged in a laminate state are connected in an integral structure.

Description

  The present invention relates to a battery pack in which a plurality of unit cells are stacked to form a battery stack.

  The battery pack can increase the output voltage by increasing the number of batteries connected in series. For this reason, battery packs used in applications requiring high output, for example, electric bicycles, electric tools, electric cars, hybrid cars, and the like, connect a plurality of unit cells in series to increase the output. Moreover, if a unit cell excellent in space efficiency is used as the battery to be stacked, a battery pack having a large capacity can be realized as a battery pack in which a large number of unit cells are stacked while keeping the outer shape relatively small. (See Patent Document 1)

JP 2011-198660 A

  The battery pack of Patent Document 1 is shown in FIGS. 1 and 2. In this battery pack, a plurality of unit cells 201 are stacked in the thickness direction to form a battery stack 209, a pair of end plates 204 are disposed on the end surfaces in the stacking direction, and the battery stack 209 is fixed in a stacked state. . The electrode tab 203 protruding from each unit cell 201 in the direction of the laminated surface is provided with a bent piece 203A by bending the tip at a right angle. The unit cell 201 is stacked in such a manner that the adjacent electrode tabs 203 stacked adjacent to each other are connected in series, and the bent pieces 203A of the positive and negative electrode tabs 203 are stacked, and the stacked portion is connected to the bus bar 205. And a nut 208, and a set screw 207 is screwed to connect the electrode tabs 203 of the unit cells 201 stacked adjacent to each other.

  In the above battery pack, the nut 208 is disposed inside the U-shaped electrode tab 203, and thus the nut 208 is fixed to the insulating holder 206 in order to place the nut 208 in a fixed position. The insulating holder 206 is inserted into the inside of the U-shaped electrode tab 203 as an elongated rod shape, and the nut 208 is disposed at a fixed position. Further, the plurality of insulating holders 206 are connected at the ends so that the insulating holders 206 can be inserted into the U-shaped electrode tab 203 together.

  In this battery pack, the nut 208 is placed at a fixed position by the insulating holder 206, so that the set screw 207 is screwed into the nut 208 through the bus bar 205 and the bent piece 203A on which the electrode tab 203 is laminated. The batteries 201 can be connected in series. However, the battery pack having this structure has a drawback that the electrode tab 203 is damaged when subjected to vibration. This is because, as indicated by the arrows in FIG. 2, the main body of the unit cell 201 and the tip of the electrode tab 203 are vibrated in a different state and move relative to each other.

  The present invention has been developed for the purpose of solving the above-mentioned drawbacks. An important object of the present invention is to provide a battery pack that has a structure in which electrode tabs of stacked unit cells are connected by a bus bar and can effectively prevent damage to the electrode tabs against vibration.

Means for Solving the Problems and Effects of the Invention

The battery pack of the present invention has the following configuration in order to achieve the above-described object.
The battery pack includes a prismatic battery stack 9 formed by stacking a plurality of plate-shaped unit cells 1 each having a positive electrode tab 3A and a negative electrode tab 3B, and the unit cell 1 constituting the battery stack 9 A bus bar connected to the electrode tab 3 and connected to the unit cell 1 and a bus bar 5 connected to each electrode tab 3 facing the stacked unit cell 1 and having a voltage difference. And an electrode insulating separator 6 made of an insulating material that insulates each other. The electrode insulating separator 6 has an exposed surface 6X exposed on the outer peripheral surface of the battery stack 9, and a connecting bar 10 extending in the stacking direction of the unit cells 1 is connected to the exposed surface 6X of each electrode insulating separator 6. Thus, the electrode insulating separators 6 arranged in a stacked state are connected to each other by a connecting bar 10 in an integrated structure.

  The above battery pack has a structure in which unit cells are stacked to form a battery stack, and the electrode tabs of the unit cells are connected by bus bars, so that the volume efficiency is increased, that is, the charging / discharging capacity with respect to the volume is increased, and vibration is generated. There is a feature that can effectively prevent the electrode tab from being damaged. That is, the above battery pack has a connection bar extending in the stacking direction of the unit cells connected to the exposed surface of the electrode insulating separator exposed on the outer peripheral surface of the battery stack, and the electrode tab is sandwiched between the connection bars. This is because the electrode insulating separators arranged in a stacked state are connected in an integrated structure. Battery packs that are integrated by connecting electrode insulation separators in a stacked state with a connection bar can prevent vibration of the electrode insulation separator, and the electrode insulation separator does not vibrate and the electrode tab is not deformed. Breakage of the electrode tab can be effectively prevented.

  In the battery pack of the present invention, the battery stack 9 has a holding wall 22 that places the unit cell 1 on the inner side of the bottom plate 21 that is sandwiched between the unit cells 1 to be stacked and that is disposed at a fixed position. A holder 2 is provided, and the battery holder 2 and the electrode insulating separator 6 can be integrally formed with an insulating plastic, and the electrode insulating separator 6 and the battery holder 2 can be connected to an integral structure.

  The above battery pack has a feature that can effectively prevent the electrode tab from being damaged by vibration. This is because the above battery pack is integrally formed of plastic with a battery holder that places the unit cells in place and an electrode insulating separator that insulates the bus bars with a voltage difference, and the electrode insulating separator and the battery holder are integrated. This is because it is linked to the structure. A battery pack having a battery holder and an electrode insulating separator as an integral structure is vibrated, and the electrode insulating separator and the battery holder are not vibrated separately and are vibrated as a whole. For this reason, the electrode insulating separator does not vibrate relative to the battery holder or the unit cell and the electrode tab is not deformed, and the electrode tab can be effectively prevented from being damaged by the vibration.

  Moreover, since the electrode insulating separator is connected to the battery holder in an integrated structure, there is a feature that the assembly can be simplified. This is because the battery holders are stacked and the electrode insulating separator is also placed at a fixed position.

In the battery pack of the present invention, the unit cell 1 has a planar main surface 1A and a rectangular outer shape, and a positive electrode tab 3A and a negative electrode tab 3B are arranged on one side of the square, The bottom plate 21 of the holder 2 has the same quadrangle as the outer shape of the unit cell 1, and the electrode insulating separator 6 can be provided on one side of the outer periphery of the square bottom plate 21, and the holding wall 2 can be provided on three sides.
In the battery pack described above, the electrode insulating separator can be arranged at a fixed position with the battery holder while the unit cell is arranged at a fixed position so as not to be displaced with the battery holder.

  In the battery pack of the present invention, the unit cell 1 has a planar main surface 1A and a rectangular outer shape, and a positive electrode tab 3A and a negative electrode tab 3B are arranged on one side of the square, The positive and negative electrode tabs 3 are located in a plane parallel to the stacking surface and protrude from the outer periphery, and the electrode tabs 3A of the positive electrodes of the respective unit cells 1 are arranged in a line apart in the stacking direction of the unit cells 1. Furthermore, the negative electrode tabs 3B can be arranged in one row apart in the stacking direction, and the positive electrode tabs 3A and the negative electrode tabs 3B can be arranged in two rows. Further, the bus bar 5 is provided with a step bent portion 5C in the middle so that both ends are connected to the positive and negative electrode tabs 3 of the adjacent unit cell 1, and at one end of the step bent portion 5C, A positive electrode connecting portion 5A connected to the positive electrode tab 3A of the unit cell 1 is provided, and a negative electrode connecting portion 5B connected to the negative electrode tab 3B of the unit cell 1 is provided at the other end. 5A is connected to the positive electrode tab 3A of the unit cell 1, the negative connection unit 5B is connected to the negative electrode tab 3B of the unit cell 1, and the unit cell 1 is formed by stacking adjacent with the bus bar 5. Can be connected in series.

  The battery pack described above is characterized in that the electrode tabs facing the stacked unit cells can be reliably insulated with the electrode insulating separator while the electrode insulating separator is disposed at a fixed position via the battery holder. In particular, in the above battery pack, the electrode tab and the bus bar of the unit cell are arranged in a plane parallel to the battery stacking surface to connect the stacking portions, and further, the voltage difference between the battery pack is arranged in a posture parallel to the stacking surface. Since the electrode insulating separator is disposed between certain bus bars, the bus bars facing each other can be reliably insulated by the electrode insulating separator.

In the battery pack of the present invention, a plurality of through holes 3x and 5x are provided in the electrode tab 3 of the unit cell 1 and the positive electrode connecting portion 5A and the negative electrode connecting portion 5B of the bus bar 5, respectively. The electrode tab 3 is fixed and electrically connected to the bus bar 5 with a set screw 7 inserted into the hole 3x and the through hole 5x of the bus bar 5, and the electrode tab 3 of the adjacent unit cell 1 is connected to the bus bar. The set screws 7 fixed to 5 can be arranged while being displaced in the direction parallel to the laminated surface of the unit cells 1.
The above battery pack has a structure in which the electrode tab is fixed to the bus bar with a set screw, so that the electrode tab can be electrically connected to the bus bar in a stable and low resistance state, and is also set apart from the battery stacking direction. Therefore, there is a feature that the set screws can be insulated in an ideal state without narrowing the stacking interval of the unit cells without approaching the set screws having a voltage difference.

In the battery pack of the present invention, the electrode insulating separator 6 is disposed between the bus bars 5 connected to the electrode tab 3A of the positive electrode of the unit cell 1 disposed adjacent to the positive electrode insulating block portion 6Ax, and the negative electrode The negative insulating block portion 6Ay disposed between the bus bars 5 connected to the electrode tab 3B is connected by a connecting portion 6B, and the exposed surface is exposed to the positive insulating block portion 6Ax and the negative insulating block portion 6Ay. 6X is provided, the connecting bar 10 can be connected to the exposed surface 6X of the positive insulating block 6Ax, and the connecting bar 10 can also be connected to the exposed surface 6X of the negative insulating block 6Ay.
In the above battery pack, both the positive insulating block portion that insulates the bus bar connected to the positive electrode tab and the negative insulating block portion that insulates the bus bar connected to the negative electrode tab are connected by a connecting bar. Therefore, the entire vibration of the electrode insulating separator can be effectively prevented, and damage due to vibration of the positive electrode tab and the negative electrode tab can be reliably prevented.

The battery pack of the present invention can be fixed to the exposed surface 6 </ b> X of each electrode insulating separator 6 by screwing the connecting bar 10.
Since this battery pack can firmly fix the connecting bar to each electrode insulating separator, it is possible to effectively prevent vibration of the electrode insulating separator and prevent damage to the electrode tab.

In the battery pack of the present invention, the electrode insulating separator 6 can be disposed in a non-connected state to the bus bar 5 and the electrode tab 3.
The above battery pack can prevent a thermal failure of the electrode insulating separator. This is because the electrode insulating separator is not connected to both the electrode tab and the bus bar, and heat conduction from the electrode tab or bus bar that generates heat can be reduced. For this reason, the battery pack can reliably prevent adverse effects such as thermal deformation of the electrode insulating separator, and can insulate the electrode tab and the bus bar in a preferable state over a long period of time.

In the battery pack of the present invention, the electrode insulating separator 6 can have through hole accommodating portions 6 a and 6 b for guiding the set screw 7.
In the above battery pack, the set screw is placed in the electrode insulation separator housing, so a thick electrode insulation separator with excellent insulation performance is placed between the opposing electrode tabs to ensure a bus bar with a voltage difference. Can be insulated. In the assembly process, the set screw can be fixed to the through hole of the bus bar from the through hole, so that the electrode tab and the bus bar are sandwiched by the electrode insulating separator, that is, the electrode tab is stacked on the bus bar by the electrode insulating separator. The set screw can be fixed to the bus bar. For this reason, it can be assembled efficiently and easily without applying an excessive deformation force to the electrode tab.

In the battery pack of the present invention, the bus bar 5 has a female screw hole 16 into which a set screw 7 is screwed, and the electrode tab 3 is fixed to the bus bar 5 by screwing the set screw 7 into the female screw hole 16. Can do.
The above battery pack can be electrically connected by securely laminating the electrode tab to the bus bar by directly screwing the set screw into the bus bar without using a nut.

In the battery pack of the present invention, the electrode insulating separator 6 includes a gap 6C in which the stepped bent portion 5C of the bus bar 5 is disposed, and the insulating rib 6D that insulates the bus bar 5 having a voltage difference is provided in the gap 6C. Can do.
The above battery pack can reduce heat conduction from the electrode tab and bus bar to the electrode insulating separator while easily setting the bus bar at a fixed position.

  In the battery pack of the present invention, the unit cell 1 can be a laminated battery. Further, in the battery pack of the present invention, the unit cell 1 can be either a lithium polymer battery or a lithium ion battery.

It is a disassembled perspective view of the conventional battery pack. It is a vertical sectional view of the battery stack of the battery pack shown in FIG. It is a perspective view of the battery pack concerning one embodiment of the present invention. FIG. 4 is an exploded perspective view of the battery pack shown in FIG. 3. FIG. 4 is a vertical sectional view of the battery pack shown in FIG. 3. It is a perspective view of a unit cell. It is a perspective view of a battery holder. It is a bottom perspective view of the battery holder shown in FIG. It is a perspective view of a bus bar. It is an expanded sectional view which shows the connection structure of a set screw and a bus bar. It is an expanded sectional view which shows another example of the connection structure of a set screw and a bus-bar. It is the disassembled perspective view which looked at the electrode insulation separator adjacent up and down from the lower side. FIG. 6 is a cross-sectional view showing an assembly process of the battery pack shown in FIG. 5. FIG. 6 is a cross-sectional view showing an assembly process of the battery pack shown in FIG. 5. FIG. 6 is a cross-sectional view showing an assembly process of the battery pack shown in FIG. 5. FIG. 6 is a cross-sectional view showing an assembly process of the battery pack shown in FIG. 5. FIG. 6 is a cross-sectional view showing an assembly process of the battery pack shown in FIG. 5.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the embodiment described below exemplifies a battery pack for embodying the technical idea of the present invention, and the present invention does not specify the battery pack as follows. In addition, the member shown by the claim is not what specifies the member of embodiment. In particular, the dimensions, materials, shapes, relative arrangements, and the like of the constituent members described in the embodiments are not intended to limit the scope of the present invention only to the description unless otherwise specified. It is just an example. Note that the size, positional relationship, and the like of the members shown in each drawing may be exaggerated for clarity of explanation. Furthermore, in the following description, the same name and symbol indicate the same or the same members, and detailed description thereof will be omitted as appropriate. Furthermore, each element constituting the present invention may be configured such that a plurality of elements are constituted by the same member and the plurality of elements are shared by one member, and conversely, the function of one member is constituted by a plurality of members. It can also be realized by sharing. In addition, the contents described in some examples and embodiments may be used in other examples and embodiments.

  The battery pack shown in FIGS. 3-5 is laminated | stacked on the battery laminated body 9 formed by laminating | stacking the several unit cell 1, and the battery laminated body 9, and has fixed the battery laminated body 9 in the laminated state. Between the base plate 4, the bus bar 5 connected to the electrode tab 3 of each unit cell 1 constituting the cell stack 9 and connecting the unit cell 1, and the electrode tab 3 of the stacked unit cell 1 And an electrode insulating separator 6 that insulates the electrode tab 3 from the bus bar 5 connected thereto.

(Battery laminate 9)
The battery stack 9 includes a plurality of unit cells 1, a battery holder 2 in which the unit cells 1 are disposed at fixed positions, and a cushion sheet 13 disposed between the bottom surface of the battery holder 2 and the unit cells 1. . In the illustrated battery stack 9, ten unit cells 1 are stacked. However, the battery stack does not specify the number of unit cells to be stacked, and can be, for example, 5 to 30, preferably 5 to 20. The unit cell 1 is a lithium polymer battery. However, the unit cell is not necessarily specified as a lithium polymer battery, and any other unit cell that can be charged, such as a lithium ion battery, can be used.

  In the battery stack 9, the positive electrode tabs 3A of each unit cell 1 are arranged in one row apart in the stacking direction of the unit cells 1, and the negative electrode tab 3B is also separated in the stacking direction in one row. The unit cells 1 are stacked so that the positive electrode tab 3A and the negative electrode tab 3B are arranged in two rows. The battery stack 9 is connected to each other in series by connecting the left and right electrode tabs 3 of the unit cells 1 stacked adjacent to each other with a bus bar 5.

(Unit cell 1)
The unit cell 1 is a flat battery having a rectangular outer shape as shown in the perspective view of FIG. The unit cell 1 in FIG. 6 is a laminate battery. However, the unit cell is not specified as a laminate battery, and all secondary batteries that can be stacked to form a battery stack, such as a metal outer can, are sealed with a sealing plate and filled with an electrode body and an electrolyte. You can also use a metal case secondary battery. A laminated battery has an aluminum film laminated with a plastic film or the like superimposed on an electrode body from above and below and welded at its end face. Each unit cell 1 has a rectangular outer shape, and has a positive electrode tab 3A on one side (left side in FIG. 6) and a negative electrode tab 3B on the other side (right side in FIG. 6). It is arranged. The electrode tab 3 is a thin metal plate, and protrudes from one side of the quadrilateral in a posture positioned in a plane parallel to the main surface 1A of both sides of the unit cell 1, that is, a plane parallel to the stack surface of the battery stack 9.

(Battery holder 2)
The battery holder 2 is formed by molding an insulating plastic, and is provided with holding walls 22 on the three sides of a rectangular bottom plate 21 for placing the unit cells 1 inside and arranging them in a fixed position. Since the battery holder 2 is formed by integrally forming the electrode insulating separator 6, the holding wall 22 is provided on three sides of the bottom plate 21 having a rectangular outer shape, and the electrode insulating separator 6 is provided on one side. The battery holder 2 is stacked in a state where the unit cell 1 is disposed inside the holding wall 22. The battery stack 9 is stacked in multiple stages with the holding walls 22 of the battery holders 2 to be stacked in contact with each other. The battery holder 2 is laminated by bonding the unit cell 1 placed inside the holding wall 22 to the bottom plate 21 via an adhesive tape 14 such as a double-sided adhesive tape.

  The battery holder 2 of FIGS. 7 and 8 is provided with a protruding portion 23 on the outside of the holding wall 22, and a connecting hole 24 through which a connecting screw 15 </ b> A as a connecting tool 15 is inserted. The connector 15 connects the battery holder 2 and the base plate 4 stacked on each other. A predetermined number of battery holders 2 in which the unit cells 1 are placed are stacked on the base plate 4 to form a battery stack 9. Further, the battery stack 9 is fixed to the base plate 4 via a connection screw 15 </ b> A inserted through the connection hole 24 of the battery holder 2.

  As shown in the figure, the electrode insulating separator 6 formed integrally with the battery holder 2 is disposed at a fixed position via the battery holder 2. However, the battery holder does not necessarily need to integrally form the electrode insulating separator. The electrode insulating separator that is not integrally molded with the battery holder is molded of plastic as a separate part separated from the battery holder. This electrode insulation separator, that is, an electrode insulation separator that is not connected to the battery holder, is disposed at a fixed position via a set screw 7 that fixes an electrode tab 3 to be described later to the bus bar 5, and a fixture is fixed to the outer surface. And placed in place.

(Base plate 4)
3-5, the battery laminated body 9 has arrange | positioned the baseplate 4 on the upper surface, connects the battery laminated body 9 to the baseplate 4 with the connector 15, and has fixed the unit cell 1 in the lamination | stacking state. . The base plate 4 has a plate shape and is approximately the same size as this so that the main surface 1A of the unit cell 1 can be completely covered. The base plate 4 is preferably made of plastic having excellent insulating properties. However, if insulation can be ensured, it may be metallic with higher strength.

(Connector 15)
The base plate 4 disposed on one surface of the battery stack 9 is fixed by a connector 15. The connecting tool 15 shown in the figure is a connecting screw 15A. As shown in FIG. 4, the connecting tool 15 of the connecting screw 15A is inserted into the connecting hole 24 of the protruding portion 23 provided to protrude outside the holding wall 22 of the battery holder 2, and the base plate 4 is screwed into the tip with a nut 15B. Fix it.

(Bus bar 5)
The bus bar 5 is connected to the electrode tab 3 of the unit cell 1 constituting the battery stack 9 and connects the adjacent unit cells 1 in series. As shown in FIG. 9, the bus bar 5 is provided with a step bent portion 5 </ b> C in the middle so that both end portions can be connected to the positive and negative electrode tabs 3 of the adjacent unit cell 1. Further, the bus bar 5 has a positive electrode connecting portion 5A connected to the positive electrode tab 3A of the unit cell 1 at one end of the step bent portion 5C and a negative electrode of the unit cell 1 at the other end. A negative electrode connection portion 5B is provided to connect to the electrode tab 3B. The positive electrode connecting portion 5A and the negative electrode connecting portion 5B are located in planes parallel to each other. The bus bar 5 has the positive electrode connecting portion 5A connected to the positive electrode tab 3A of the unit cell 1 and the negative electrode connecting portion 5B connected to the negative electrode tab 3B of the unit cell 1 so as to be stacked adjacent to each other. Are connected in series.

  The bus bar 5 is electrically connected by laminating the electrode tabs 3 and fixing the electrode tabs 3 with set screws 7 penetrating the electrode tabs 3. As shown in the enlarged sectional view of FIG. 10, the set screw 7 passes through the through hole 3 x of the electrode tab 3 and is screwed into the female screw hole 16 which is the through hole 5 x of the bus bar 5. Secure to. The bus bar 5 is provided with a plurality of through holes 5x in the positive connection portion 5A and the negative connection portion 5B, respectively. The bus bar 5 of FIG. 9 is provided with four through holes 5x in the positive connection portion 5A and the negative connection portion 5B. Since the electrode tab 3 is fixed to the bus bar 5 with a set screw 7 inserted into the through hole 5x of the bus bar 5, the electrode tab 3 of the unit cell 1 is also provided with a plurality of through holes 3x. The unit cell 1 of FIG. 6 is provided with four through holes 3x in each electrode tab 3. The set screw 7 is inserted into the through hole 3 x of the electrode tab 3 and the through hole 5 x of the bus bar 5 to fix the electrode tab 3 to the bus bar 5. The bus bar 5 having the through hole 5x as the female screw hole 16 is screwed with a set screw 7 to fix the electrode tab 3. In the battery pack of FIG. 5, set screws 7 formed by fixing the electrode tabs 3 of the unit cells 1 stacked adjacent to each other vertically to the bus bar 5 are alternately positioned in a direction parallel to the layered surface of the unit cells 1. Displaced. That is, two appropriate locations are selected from the connecting portion of the bus bar 5 facing each other and the four through holes 5x and 3x of the electrode tab 3, and the electrode tab 3 and the bus bar 5 are connected to each other via the set screw 7 at the two locations. It is connected. Furthermore, the set screws 7 that connect the electrode tabs 3 and the bus bars 5 facing each other in the adjacent unit cells 1 are arranged so as not to face each other in the stacking direction of the unit cells 1. That is, in the figure, the position of the set screw 7 that connects the electrode tab 3 of the unit cell 1 arranged in the upper stage and the bus bar 5 and the electrode tab 3 of the unit cell 1 arranged in the lower stage and the bus bar 5 are connected. The position of the set screw 7 is shifted in the horizontal direction so as not to face each other. Therefore, in the battery pack, as shown in FIG. 5, a plurality of set screws 7 arranged in the vertical direction are arranged in a staggered manner, and the electrode tab 3 is fixed to the bus bar 5. This fixing structure does not have the set screw 7 for fixing the electrode tab 3 of the upper unit cell 1 on the set screw 7, and can prevent the set screw 7 having a voltage difference from approaching. For this reason, even if the lamination | stacking space | interval of the unit cell 1 is narrowed, the set screw 7 with a voltage difference can be insulated in an ideal state.

  The above bus bar 5 is provided with a female screw hole 16 on the inner surface of the through hole 5x. The bus bar 5 can fix the electrode tab 3 by screwing a set screw 7 into the female screw hole 16. This fixing structure can easily fix the set screw 7 to the bus bar 5 without using a nut. Further, this through hole allows the burr to protrude from the surface of the bus bar, and a female screw is also provided on the inner surface of the burr so that the set screw can be more securely fixed. However, the through hole of the bus bar is not necessarily a female screw hole. As shown in FIG. 11, the bus bar 5 has a nut 17 into which a set screw 7 is screwed on the surface of the through hole 5 x, and the nut 17 is screwed with the tip of the set screw 7 passing through the electrode tab 3 and the bus bar 5, The electrode tab 3 can also be fixed to the bus bar 5. The nut 17 can be disposed in a storage portion 6b formed in the electrode insulating separator 6 described later. In the above battery pack, the electrode tab 3 is fixed to the bus bar 5 with the set screw 7, but the electrode tab can also be fixed to the bus bar by welding. This fixing structure electrically connects the electrode tab to the bus bar without using a set screw.

(Electrode insulating separator 6)
The electrode insulating separator 6 is disposed between the opposing electrode tabs 3 of the stacked unit cells 1, insulates the adjacent electrode tabs 3, and further connects to the electrode tabs 3 with a voltage difference between the bus bars 5. Also insulate. Since the electrode insulating separator 6 insulates the adjacent electrode tab 3 and the bus bar 5, it is formed of an insulating plastic. As shown in FIGS. 7 and 8, the electrode insulating separator 6 is a pair of insulating block portions disposed between the electrode tabs 3 of the unit cells 1 stacked one above the other and between the opposing bus bars 5. 6A is connected by a connecting part 6B on the battery side. The pair of insulating block portions 6A includes a positive insulating block portion 6Ax disposed between the positive electrode tabs 3A and a negative insulating block portion 6Ay disposed between the negative electrode tabs 3B. The pair of insulating block portions 6A are separated from each other by a connecting portion 6B so that the stepped bent portion 5C of the bus bar 5 can be guided therebetween, and a gap 6C is provided between the insulating block portions 6A. In this gap 6 </ b> C, insulating ribs 6 </ b> D that are inserted between the upper and lower bus bars 5 and insulate the bus bars 5 are arranged. The insulating rib 6D is connected to the connecting portion 6B on the battery side. The insulating rib 6D is connected to the connecting portion 6B in a posture inclined at an angle equal to the inclination of the step bent portion 5C of the bus bar 5.

  The electrode insulating separator 6 is disposed between the bus bars 5 having a voltage difference, but is not connected to both the bus bar 5 and the electrode tab 3. Furthermore, the battery pack of FIG. 5 does not connect the electrode insulating separator 6 to the set screw 7 as shown in the enlarged cross-sectional view of the main part of FIG. The electrode insulating separator 6 described above can reduce heat conduction from the set screw 7, the bus bar 5, and the electrode tab 3, and prevent the adverse effect of being deformed or melted by the heat generation of the electrode tab 3.

  As shown in the sectional views of FIGS. 5 and 10, the electrode insulating separator 6 is disposed between the bus bars 5 connected to the electrode tabs 3 facing each other in the adjacent unit cell 1. The screw 7 protrudes. Therefore, the electrode insulating separator 6 is provided with storage portions 6 a and 6 b that guide the portions where the set screw 7 protrudes from the surfaces of the electrode tab 3 and the bus bar 5. The storage portion 6a is a through hole that can guide a portion from which the set screw 7 protrudes. However, the storage part does not necessarily have to be all through-holes. In the electrode insulating separator 6 of FIGS. 5 and 10, the storage portion 6 a that guides the head of the set screw 7 is a through hole, and the storage portion 6 b that guides the tip of the set screw 7 is a recess. The electrode insulating separator 6 having a housing portion 6 a that guides the head of the set screw 7 as a through hole can be fixed by inserting a screwdriver into the through hole and screwing the set screw 7 into the bus bar 5.

  In the illustrated electrode insulating separator 6, four insulating portions 6 a and 6 b are provided in each insulating block portion 6 </ b> A. The four storage portions 6a and 6b are provided at positions facing the four through holes 3x of the electrode tabs 3 of the stacked unit cells 1, respectively. Further, the electrode insulating separator 6 is provided with two storage portions 6a and two storage portions 6b alternately in each insulating block portion 6A. Here, as shown in FIG. 12, the electrode insulating separators 6 that are vertically adjacent to each other have a storage portion 6a that guides the head portion of the set screw 7 and a storage portion 6b that guides the tip end portion of the set screw 7. Four storage portions 6a and 6b are provided so as to be in opposite positions. As described above, the set screws 7 for fixing the electrode tabs 3 of the unit cells 1 stacked adjacent to each other vertically to the bus bar 5 are alternately displaced so as not to face each other in the stacking direction of the unit cells 1. It is for arranging. Accordingly, the electrode insulating separator 6 disposed adjacent to the upper and lower sides is provided with two types of first electrode insulating separator 6M and second electrode insulating separator provided so that the positions of the storage portions 6a and 6b are opposite to each other. 6N are alternately laminated. As shown in FIG. 12, the first electrode insulating separator 6M and the second electrode insulating separator 6N that are adjacent to each other are provided so that the one storage portion 6a faces the other storage portion 6b. That is, in the electrode insulating separators 6 adjacent to each other, the storage portion 6a of the first electrode insulating separator 6M and the storage portion 6b of the second electrode insulating separator 6N face each other, and the storage portion 6b of the first electrode insulating separator 6M The accommodating portion 6a of the second electrode insulating separator 6N is opposed to the second electrode insulating separator 6N. The electrode insulating separators 6 stacked in multiple stages are formed by alternately stacking the first electrode insulating separator 6M and the second electrode insulating separator 6N in which the positions of the storage portions 6a and 6b are opposite to each other. As shown in FIG. 2, a plurality of set screws 7 arranged vertically are arranged in a staggered manner.

  The electrode insulating separator 6 integrally formed with the battery holder 2 and integrated with the battery holder 2 is disposed at a predetermined position via the battery holder 2. The electrode insulating separator that is not integrally formed with the battery holder is disposed at a fixed position by guiding a set screw to the storage portion.

  Further, the electrode insulating separator 6 of FIGS. 3 and 4 has an exposed surface 6X exposed on the outer peripheral surface of the battery stack 9, and extends in the stacking direction of the unit cells 1 on the exposed surface 6X of each electrode insulating separator 6. The connecting bars 10 are connected, and the electrode insulating separators 6 arranged in a stacked state with the connecting bars 10 are connected in an integrated structure. In the unit cell 1 having a quadrangular outer shape, positive and negative electrode tabs 3 protrude from one outer peripheral surface of the quadrangle. The battery laminate 9 is formed by laminating the unit cells 1 so that the outer peripheral surfaces of the electrode tabs 3 are positioned on the same plane, and connecting the electrode tabs 3 in series with the bus bars 5. 6 is arranged. Therefore, in the battery stack 9, one prismatic flat surface is an exposed stacked surface 9 </ b> X in which the side surface of the bus bar 5 and the exposed surface 6 </ b> X of the electrode insulating separator 6 are alternately stacked. The connecting bar 10 fixed to the exposed surface 6X of the electrode insulating separator 6 is an elongated plate shape that extends in the stacking direction of the unit cells 1 on the exposed stacked surface 9X, and is fixed to the exposed surface 6X of each electrode insulating separator 6. It is fixed with screws 18. The fixing screw 18 passes through the connecting bar 10 and is fixed to the electrode insulating separator 6 by screwing. However, the connecting structure in which the connecting bar 10 is connected to the exposed surface 6X of the electrode insulating separator 6 is not limited to this structure. For example, the connecting bar 10 is bonded and fixed to the exposed surface 6X of the electrode insulating separator 6, Alternatively, a hook-shaped locking piece is provided on the electrode insulating separator, a connecting hole is provided on the connecting bar for inserting and connecting the locking piece, and the locking piece is inserted through the connecting hole for connection. It can also be set as the connection structure.

  The electrode insulating separator 6 shown in FIGS. 3 and 4 is connected to the integrated structure by two rows of connecting bars 10. One connecting bar 10 is between positive and negative electrode tabs 3 </ b> A adjacent to each other, and has a voltage difference between the bus bars 5. The positive insulating block 6 </ b> Ax that insulates the positive connecting portion 5 </ b> A of the bus bar 5. The other connecting bar 10 is connected between the negative electrode tabs 3B adjacent to each other in the vertical direction and is connected between the bus bars 5 having a voltage difference and insulating the negative connection portion 5B of the bus bar 5. It is connected to the insulating block portion 6Ay.

  The above battery pack is assembled as follows. The battery pack of FIGS. 3 to 5 has the circuit board 8 mounted on the upper surface. However, as shown in FIGS. 13 to 17, the battery pack is inverted upside down, that is, the base plate 4 for fixing the circuit board 8 is assembled. It is assembled by placing it below.

(1) The unit cell 1 is disposed inside the holding wall 22 of the battery holder 2, and the unit cell 1 is bonded to the bottom plate 21 of the battery holder 2 via an adhesive tape 14 that is a double-sided adhesive tape. In this way, a predetermined number of battery holders 2 in which the unit cells 1 are arranged at a fixed position are prepared.

(2) In use, the base plate 4 disposed on the upper surface is turned upside down and placed on the horizontal table 50 as shown in FIG. Furthermore, after placing an output terminal plate 11 serving as an output terminal on the base plate 4, a battery holder 2 to which the unit cell 1 is bonded is laminated on the base plate 4 via a cushion sheet 13.
In this state, the positive electrode tab 3 </ b> A which is one (right side in the figure) of the unit cell 1 is fixed to the output terminal plate 11 with the set screw 7.

(3) Next, as shown in FIG. 14, the bus bar 5 is disposed at a fixed position of the electrode insulating separator 6 laminated on the base plate 4. The bus bar 5 includes a positive electrode connecting block 5A (on the right side in the drawing) on which the positive electrode tab 3A is disposed, and a negative electrode insulating block portion on which the negative electrode tab 3B is disposed. A negative electrode connecting portion 5B is laminated on the lower surface side of 6Ay (left side in the figure), and the step bent portion 5C is disposed in the gap 6C between the pair of insulating block portions 6A. The negative electrode connecting portion 5B of the bus bar 5 is inserted into a gap formed between the negative electrode tab 3A and the base plate 4 disposed on the lower surface of the negative insulating block portion 6Ay and is disposed at a fixed position. Further, the step bent portion 5C of the bus bar 5 is disposed on the upper surface side of the insulating rib 6D disposed in the gap 6C. The bus bar 5 is inserted into the electrode insulating separator 6 from the side surface direction (direction perpendicular to the paper surface in FIG. 14).
In this state, the negative electrode tab 3B which is the other electrode tab 3 of the unit cell 1 (left side in the figure) is fixed to the negative electrode connection portion 5B of the bus bar 5 with the set screw 7.

(4) Further, as shown in FIG. 15, the second-stage battery holder 2 to which the unit cells 1 are bonded is stacked on the lowermost-stage battery holder 2 via the cushion sheet 13. At this time, the second-stage electrode insulating separator 6 is disposed at a position facing the pair of insulating block parts 6A of the electrode insulating separator 6 in which the pair of insulating block parts 6A are stacked in the lower stage.
In this state, the positive electrode tab 3 </ b> A which is one (right side in the drawing) of the unit cell 1 is fixed to the positive connection portion 5 </ b> A of the bus bar 5 with the set screw 7. The set screw 7 is fixed while being displaced in the horizontal direction with respect to the set screw 7 arranged at the lower stage.

(5) Further, as shown in FIG. 16, the bus bar 5 is disposed at a fixed position of the second-stage electrode insulating separator 6. The bus bar 5 includes a positive electrode connecting block 5A (on the right side in the drawing) on which the positive electrode tab 3A is disposed, and a negative electrode insulating block portion on which the negative electrode tab 3B is disposed. A negative electrode connecting portion 5B is laminated on the lower surface side of 6Ay (left side in the figure), and the step bent portion 5C is disposed in the gap 6C between the pair of insulating block portions 6A. The negative electrode connecting portion 5B of the bus bar 5 is inserted into a gap formed between the negative electrode tab 3A disposed on the lower surface of the negative insulating block portion 6Ay and the lower negative insulating block portion 6Ay and disposed at a fixed position. The Further, the step bent portion 5C of the bus bar 5 is disposed on the upper surface side of the insulating rib 6D disposed in the gap 6C. The bus bar 5 is inserted into the electrode insulating separator 6 from the side surface direction (direction perpendicular to the paper surface in FIG. 16).
In this state, the negative electrode tab 3B which is the other electrode tab 3 of the unit cell 1 (left side in the figure) is fixed to the negative electrode connection portion 5B of the bus bar 5 with the set screw 7. The set screw 7 is fixed while being displaced in the horizontal direction with respect to the set screw 7 arranged at the lower stage.

(6) Similarly, the steps (4) and (5) are repeated to form a battery stack 9 by stacking a predetermined number of battery holders 2, and the positive and negative of the unit cells 1 stacked on each other. The electrode tabs 3 are connected in series via the bus bar 5.

(7) As shown in FIG. 17, the positive electrode tab 3A, which is the electrode tab 3 on one side (right side in the figure) of the unit cells 1 stacked at the top, is connected to the positive connection portion 5A of the bus bar 5 with a set screw 7 The negative electrode tab 3B, which is the other electrode tab 3 (left side in the figure) of the unit cell 1, is fixed to the output terminal plate 12 with a set screw 7. The output terminal board 12 shown in the figure is bent in an inverted L shape, and the connecting portion 12A is arranged on the lower surface of the negative insulating block portion 6Ay and the negative electrode tab 3A and the lower negative insulating block portion 6Ay. It is inserted in a gap formed between the two and placed at a fixed position. The output terminal plate 12 has a connection portion 12A connected to the electrode tab 3 of the unit cell, and a distal end portion of an extension portion extended from the connection portion is coupled to the base plate 4 via a set screw 7.

(8) A predetermined number of battery holders 2 are stacked as described above, and the battery stack 9 in which a predetermined number of unit cells 1 are stacked is connected to the base plate 4 via the connector 18. Further, on the exposed laminated surface 9X of the battery laminate 9, the upper and lower adjacent positive electrode insulating block portions 6Ax are connected by the connecting bar 10, and the upper and lower adjacent negative electrode insulating block portions 6Ay are connected by the connecting bar 10. The connecting bar 10 is fixed to the exposed surface 6 </ b> X of each electrode insulating separator 6 with a fixing screw 18.
The battery stack 9 integrally connected to the base plate 4 is turned upside down to obtain the battery pack shown in FIG.

  The battery pack according to the present invention can be suitably used as a relatively large power supply device for electric motorcycles, electric vehicles, assist bicycles, and the like.

DESCRIPTION OF SYMBOLS 1 ... Unit cell 1A ... Main surface 2 ... Battery holder 3 ... Electrode tab 3A ... Electrode tab of positive electrode
3B ... Negative electrode tab
3x ... through hole 4 ... base plate 5 ... bus bar 5A ... positive electrode connection
5B ... Negative electrode connection
5C ... Step bending part
5x ... through hole 6 ... electrode insulating separator 6M ... first electrode insulating separator
6N ... second electrode insulation separator
6A ... Insulation block
6Ax: Positive insulating block
6Ay ... Negative insulating block
6X ... exposed surface
6B ... Connection part
6C ... Gap
6D ... Insulating rib
6a ... Storage part
6b ... Storage part 7 ... Set screw 8 ... Circuit board 9 ... Battery laminated body 9X ... Exposed laminated surface 10 ... Connection bar 11 ... Output terminal board 12 ... Output terminal board 12A ... Connection part
12B ... Extension part 13 ... Cushion sheet 14 ... Adhesive tape 15 ... Connector 15A ... Connection screw
15B ... Nut 16 ... Female screw hole 17 ... Nut 18 ... Fixing screw 21 ... Bottom plate 22 ... Holding wall 23 ... Protrusion 24 ... Connection hole 50 ... Horizontal table 201 ... Unit 203 ... Electrode tab 203A ... Bending piece 204 ... End plate 205 ... Bus bar 206 ... Insulating holder 207 ... Set screw 208 ... Nut 209 ... Battery laminate

Claims (13)

A prismatic battery laminate (9) formed by laminating a plurality of plate-like unit cells (1) each having a positive electrode tab (3A) and a negative electrode tab (3B);
A bus bar (5) connected to the electrode tab (3) of the unit cell (1) constituting the cell stack (9) and connected to the unit cell (1);
Electrode insulation made of an insulating material disposed between the bus bars (5) connected to the opposing electrode tabs (3) of the stacked unit cells (1) to insulate the bus bars (5) having a voltage difference from each other. With a separator (6),
The electrode insulating separator (6) has an exposed surface (6X) exposed on the outer peripheral surface of the battery stack (9), and the exposed cell (6X) of each electrode insulating separator (6) has the unit cell ( 1) a connecting bar (10) extending in the stacking direction is connected, and the electrode insulating separator (6) arranged in a stacked state by the connecting bar (10) is connected in an integrated structure. pack. The battery stack (9) is a holding wall (22) arranged in a fixed position by placing the unit cell (1) on the bottom plate (21) sandwiched between the unit cells (1) to be stacked. Battery holder (2) having
The battery holder (2) and the electrode insulating separator (6) are integrally formed of an insulating plastic, and the electrode insulating separator (6) and the battery holder (2) are connected in an integrated structure. Item 6. The battery pack according to Item 1. In the unit cell (1), the opposing main surface (1A) is planar and the outer shape is rectangular, and a positive electrode tab (3A) and a negative electrode tab (3B) are arranged on one side of the square. And
The bottom plate (21) of the battery holder (2) is the same quadrangle as the outer shape of the unit cell (1), and the electrode insulating separator (6) is provided on one side of the outer periphery of the bottom plate (21) that is a quadrangle. The battery pack according to claim 2, wherein holding walls (22) are provided on three sides. In the unit cell (1), the opposing main surface (1A) is planar and the outer shape is rectangular, and a positive electrode tab (3A) and a negative electrode tab (3B) are arranged on one side of the square. In addition, the positive and negative electrode tabs (3) are located in a plane parallel to the laminated surface and protrude from the outer periphery,
The positive electrode tabs (3A) of each unit cell (1) are separated in the stacking direction of the unit cells (1) and arranged in one row, and the negative electrode tab (3B) is also separated in the stacking direction. The positive electrode tab (3A) and the negative electrode tab (3B) are arranged in two rows,
The bus bar (5) has a step bent portion (5C) in the middle so that both ends are connected to the positive and negative electrode tabs (3) of the adjacent unit cell (1), and the step bent portion (5C ) At one end of the unit cell (1) is connected to the positive electrode tab (3A) of the unit cell (1), and at the other end of the unit cell (1). Provided with a negative electrode connection (5B) connected to the negative electrode tab (3B),
The positive connection (5A) is connected to the positive electrode tab (3A) of the unit cell (1), and the negative connection (5B) is connected to the negative electrode tab (3B) of the unit cell (1). (5) The battery pack according to any one of claims 1 to 3, wherein the unit cells (1) laminated adjacently are connected in series. A plurality of through holes (3x; 5x) are provided in the electrode tab (3) of the unit cell (1), and the positive electrode connection portion (5A) and the negative electrode connection portion (5B) of the bus bar (5), respectively. The electrode tab (3) is fixed to the bus bar (5) with a set screw (7) inserted into the through hole (3x) of the electrode tab (3) and the through hole (5x) of the bus bar (5). Are electrically connected,
Further, a set screw (7) formed by fixing the electrode tab (3) of the adjacent unit cell (1) to the bus bar (5) is positioned in a direction parallel to the layer surface of the unit cell (1). The battery pack according to claim 4, wherein the battery pack is arranged out of alignment. The electrode insulating separator (6) is a positive insulating block (6Ax) disposed between bus bars (5) connected to the positive electrode tab (3A) of the adjacent unit cell (1). ) And the negative insulating block part (6Ay) disposed between the bus bar (5) connected to the negative electrode tab (3B) by the connecting part (6B),
An exposed surface (6X) is provided on the positive insulating block (6Ax) and the negative insulating block (6Ay), and the connecting bar (10) is provided on the exposed surface (6X) of the positive insulating block (6Ax). The battery system according to any one of claims 1 to 5, wherein the battery bar is connected and the connecting bar (10) is connected to the exposed surface (6X) of the negative insulating block (6Ay).   The battery pack according to any one of claims 1 to 6, wherein the connecting bar (10) is screwed and fixed to the exposed surface (6X) of each electrode insulating separator (6).   The battery pack according to any one of claims 1 to 7, wherein the electrode insulating separator (6) is disposed in an unconnected state with the bus bar (5) and the electrode tab (3).   9. The battery pack according to claim 8, wherein the electrode insulating separator (6) has a through hole accommodating portion (6a; 6b) for guiding the set screw (7).   The bus bar (5) has a female screw hole (16) for screwing and fixing a set screw (7), and the set screw (7) is screwed into the female screw hole (16) to form an electrode tab (3). The battery pack according to any one of claims 1 to 9, wherein is fixed to the bus bar (5).   The electrode insulation separator (6) is provided with a gap (6C) for arranging the step bent portion (5C) of the bus bar (5), and the bus bar (5) having a voltage difference is provided in the gap (6C). The battery pack according to any one of claims 1 to 10, further comprising insulating ribs (6D) for insulating.   The battery pack according to any one of claims 1 to 11, wherein the unit cell (1) is a laminated battery.   The battery pack according to any one of claims 1 to 12, wherein the unit cell (1) is either a lithium polymer battery or a lithium ion battery.

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