JP2012212604A - Battery pack - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a battery pack which enhances work efficiency and productivity in production.SOLUTION: The batter pack comprises multiple unit cells 100 each having a positive electrode lead-out tab 120 and a negative electrode lead-out tab 130, a substrate 300 on which a lead-out tab connection for interconnecting the lead-out tabs having polarities different from each other of the adjacent unit cells 100 is formed, and a holder member 200 being bonded to the substrate 300 and having a lead-out tab insertion hole 215 into which the positive electrode lead-out tab 120 and the negative electrode lead-out tab 130 of the multiple unit cells 100 are inserted.

Description

  The present invention relates to a battery pack configured by connecting a plurality of secondary unit batteries such as lithium ion batteries.

  Lithium ion secondary batteries, which are charged and discharged by moving lithium ions between the negative electrode and the positive electrode, have been applied in various fields in recent years because of their high energy density and high output battery characteristics. . For example, a battery pack in which a plurality of secondary unit batteries such as lithium ion batteries are connected in series may be used as an energy source for electric assistance for bicycles.

  For the exterior of the secondary unit battery applied to such applications, a laminate film exterior material composed of a metal laminate film is often used because of its advantage of high shape flexibility and light weight.

For example, Patent Document 1 (Japanese Patent Application Laid-Open No. 2010-170799) discloses a plurality of single cells composed of a flat type non-aqueous electrolyte battery having a laminate film exterior material in relation to FIGS. An assembled battery 23 is disclosed in which 21 is laminated so that the negative electrode terminal 6 and the positive electrode terminal 7 extending to the outside are aligned in the same direction and fastened with an adhesive tape 22. In such an assembled battery 23, the plurality of single cells 21 are electrically connected to each other in series.
JP 2010-170799 A

  In the battery back disclosed in Patent Document 1, a plurality of unit cells 21 stacked so that the negative electrode terminal 6 and the positive electrode terminal 7 are aligned in the same direction are electrically connected in series. In order to connect the unit cells 21 in series, it is necessary to connect the electrodes of the adjacent unit cells 21 having different polarities. In the battery back disclosed in Patent Document 1, the unit cells adjacent to each other are connected. The electrical connecting portions 21 are arranged obliquely with respect to the stacking direction.

  Moreover, in the flat unit cell 21 having a laminate film exterior material as disclosed in Patent Document 1, the interval between the electrodes of the adjacent unit cells 21 is very short. From the above, when manufacturing the battery back disclosed in Patent Document 1, when connecting the electrodes of the adjacent unit cells 21, the electrodes placed in a narrow space are stacked while being careful of short circuits. There is a problem that it is necessary to sequentially connect in an oblique direction, the work efficiency is low, and the productivity is low.

  The present invention solves the above-described problem, and a battery pack according to the present invention includes a plurality of unit cells each having a positive electrode extraction tab and a negative electrode extraction tab, and different polarities of adjacent unit cells. A substrate on which a drawer tab coupling portion is coupled to each other, and a holder fixed to the substrate and having a hole through which the positive and negative electrode tabs of the plurality of unit cells are inserted. And a member.

  The battery pack according to the present invention is characterized in that the holder member is provided with a guide protrusion so as to sandwich the hole.

  Also, the battery pack according to the present invention is characterized in that the guide protrusion has a tapered side surface.

  According to the battery pack of the present invention, the operation of inserting the positive electrode pull-out tab and the negative electrode pull-out tab of the plurality of unit batteries into the holes of the holder member is performed, and the pull-out tabs having different polarities of the plurality of unit cells are formed on the substrate. Since it connects so that it may be connected above, the work efficiency in manufacturing a battery bag is high, and productivity improves.

It is a figure which shows the unit battery 100 which comprises the battery pack which concerns on embodiment of this invention. FIG. 3 is a diagram illustrating a state where a tab member 125 is joined to the positive electrode pull-out tab 120 of the unit battery 100. It is a figure which shows the state which provided the hole in the positive electrode extraction tab and the negative electrode extraction tab for the serial connection of the unit battery 100. FIG. It is a figure explaining the holder member 200 used when comprising the battery pack which concerns on embodiment of this invention. It is a perspective view of the holder member 200 used when comprising the battery pack which concerns on embodiment of this invention. FIG. 3 is a perspective view of a substrate 300 used in series connection of unit cells 100 in a battery pack according to an embodiment of the present invention. It is a figure explaining the battery protection member 400 used when comprising the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery connection structure 500 which comprises the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery connection structure 500 which comprises the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery connection structure 500 which comprises the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery connection structure 500 which comprises the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery connection structure 500 which comprises the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery connection structure 500 which comprises the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery connection structure 500 which comprises the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery connection structure 500 which comprises the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery connection structure 500 which comprises the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery connection structure 500 which comprises the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery connection structure 500 which comprises the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery pack which concerns on embodiment of this invention. It is a figure explaining the manufacturing process of the battery pack which concerns on embodiment of this invention. It is a figure explaining the adhesion conditions of unit cells. It is a figure explaining the other example of the adhesion conditions of the unit cells 100. It is a figure explaining the other example of the adhesion conditions of the unit cells 100. It is a figure which shows the attitude | position at the time of utilization of the battery pack which concerns on embodiment of this invention. It is a figure which shows the other example of the unit battery 100 which comprises a battery pack.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing a unit battery 100 constituting a battery pack according to an embodiment of the present invention. As the unit battery 100, a lithium ion secondary unit battery that is charged and discharged by moving lithium ions between a negative electrode and a positive electrode is used.

  The battery main body 110 of the unit battery 100 has an electrode laminate in which a plurality of sheet-like positive electrodes and a plurality of sheet-like negative electrodes are laminated via separators, and an electrolyte solution (both not shown) are rectangular in a plan view. It has a structure accommodated in a laminate film exterior material. A positive electrode extraction tab 120 and a negative electrode extraction tab 130 are extracted from the first end 111 of the battery main body 110.

  The positive electrode pull-out tab 120 and the negative electrode pull-out tab 130 are both flat and are connected to the sheet-like positive electrode and the sheet-like negative electrode directly or via a lead body, respectively, in the laminate film exterior material. The laminate film exterior material is constituted by a metal laminate film having a heat-sealing resin layer on the surface that becomes the inside of the battery. More specifically, for example, two metal laminate films are laminated to form a laminate film exterior material, and an electrode laminate having a sheet-like positive electrode, a sheet-like negative electrode, and a separator and an electrolytic solution are accommodated therein. The outer periphery (first end 111, second end 112, two side ends 113) of the laminate film exterior material is heat-sealed, so that the inside is sealed.

  Here, the metal piece drawn out from the battery body 110 made of the laminate film exterior material such as the positive electrode extraction tab 120 and the negative electrode extraction tab 130 will be referred to as a “drawer tab”, and a separator or an electrolysis will be provided inside the laminate film exterior material. A sheet-like positive electrode or a sheet-like negative electrode laminated via a liquid or the like is referred to as an “electrode”.

  In the electrode laminate, in addition to a laminate of a plurality of sheet-like positive electrodes and a plurality of sheet-like negative electrodes as described above, a laminate of a sheet-like positive electrode and a sheet-like negative electrode via a separator. The thing which makes a laminated body by winding this and compressing this is also contained.

  In the unit battery 100 as described above, the material of the positive electrode pull-out tab 120 is aluminum or an aluminum alloy, the material of the negative electrode pull-out tab 130 is nickel, and a material obtained by nickel plating other metals (nickel plating). Materials such as nickel-plated copper) and nickel and other metal clads (nickel clad materials such as nickel-copper clad) are generally used. In other words, the unit cell 100 has a positive electrode extraction tab 120 containing aluminum and a negative electrode extraction tab 130 containing nickel. In this embodiment, a positive electrode extraction tab 120 made of aluminum and a negative electrode extraction tab 130 made of nickel are used.

  In configuring the battery pack according to the present invention, the positive electrode pull-out tab 120 of the unit battery 100 and the negative electrode pull-out tab 130 of the unit battery 100 adjacent to the unit battery 100 are fixed by mechanically tightening them with bolts and nuts. And make electrical connections.

  Here, in the structure in which the positive electrode lead tab 120 containing aluminum and the negative electrode lead tab 130 containing nickel of the unit battery 100 are mechanically fixed, the conductivity deteriorates after a predetermined period of time due to a potential difference problem. there's a possibility that.

  Therefore, in the battery pack according to the present invention, the extension tab 125 containing nickel is joined to the positive electrode lead tab 120 of the unit battery 100 by welding. When a plurality of unit cells 100 are connected in series, the connection tab 125 of one unit cell 100 and the negative electrode pull-out tab 130 of the other unit cell 100 are connected to each other, thereby providing conductivity due to a potential difference problem. Solve the problem of deterioration.

  The configuration for this will be described in more detail. As shown in FIG. 1, in configuring the battery pack, the positive electrode extraction tab 120 made of aluminum in the unit battery 100 has a length a from the first end portion 111, and the negative electrode extraction tab 130 made of nickel has a first end. The length from the portion 111 is b (b> a). Next, an extension tab member 125 made of nickel is joined to the positive electrode lead tab 120 made of aluminum having a length a by ultrasonic welding so that the length from the first end portion 111 is b, It is added (see FIGS. 2 and 3). In order to connect the unit cells 100 in series, a hole 127 is provided in the additional tab member 125 as a positive electrode extraction tab, and a hole 137 is provided in the negative electrode extraction tab 130. Hereinafter, the entire drawer tab formed by joining the additional tab members 125 may be referred to as a positive electrode drawer tab 120.

  As will be described later, in the battery pack according to the present invention, when the plurality of unit batteries 100 are electrically connected, the members including nickel (addition tab member 125 and negative electrode extraction tab 130) are brought into contact with each other and pulled out. Since the tabs are mechanically connected to each other, the electrical connection portions of adjacent unit cells are electrically connected by the same kind of metal material, there is no problem of potential difference, and conductivity deterioration may occur over time. Almost disappear.

Next, in the battery pack according to the embodiment of the present invention, the holder member 200 used for electrically connecting the positive electrode extraction tab and the negative electrode extraction tab of the plurality of unit cells 100 will be described. 4A and 4B are diagrams for explaining the holder member 200. FIG. 4A is a view of the holder member 200 seen from the first main surface side, and FIG. 4B is a holder view from the second main surface side. It is the figure which looked at the member 200,
FIG. 4C is a view showing a cross section taken along line XX ′ of FIG. 4A, and FIG. 4D is a view of the holder member 200 as viewed from the side.

  The holder member 200 is a member made of synthetic resin, such as ABS, on which a first surface 210 and a second surface 250 that is in a front-back relationship with the first surface 210 are formed. In the first row 211 of the first surface 210 of the holder member 200, as shown in FIG. 4A, drawer tab insertion holes 215 are formed side by side from the top to the bottom. Similarly, on the second row 212 side of the first surface 210, a pull-out tab insertion hole 215 is formed side by side from the top to the bottom. When the unit battery 100 is attached to the holder member 200, the pull-out tab insertion hole 215 provided on the first surface 210 side is used. The drawer tab insertion hole 215 is a hole that penetrates from the first surface 210 side to the second surface 250 side, and is a hole through which the drawer tab of the unit battery 100 can be inserted.

As shown in FIG. 4A, on the upper and lower sides of the first row 211 and the second row 212, drawer tab guide ribs 203 are provided. Further, the pull-out tab routing portion 213 is sandwiched between the pull-out tab guide ribs 203 on the first row 211 side, and the pull-out tab routing portion 213 is sandwiched between the pull-out tab guide ribs 203 on the second row 212 side. A recess 214 is provided.

  On the first row 211 side, the pull-out tabs of the unit cells 100 on the end side among the plurality of unit cells 100 connected in series are arranged from the first surface 210 side based on the restriction by the pull-out tab guide ribs 203. The two surfaces 250 are guided so as to pass through the pull-out tab routing portion 213.

  Further, on the second row 212 side, the drawer tabs of the unit cells 100 on the end side among the plurality of unit cells 100 connected in series are arranged on the first surface 210 side based on the regulation by the drawer tab guide ribs 203. From the first side to the second surface 250 side, it is guided so as to pass through the drawing tab drawing recess 214.

  Of the plurality of unit batteries 100 connected in series, the pull-out tab of the unit battery 100 that is not on the end side (the upper side and the lower side of the holder member 200 in FIG. 4A) is inserted into the pull-out tab insertion hole 215. In this manner, the holder member 200 is attached. On the top and bottom (as viewed in FIG. 4A) of the pull-out tab insertion hole 215, there are provided pull-out tab guide protrusions 220 that sandwich the pull-out tab insertion hole 215 from above and below. The pull-out tab guide protrusion 220 is roughly constituted by a top portion 221 and two tapered side surfaces 222 connected to the top portion 221, and when the pull-out tab of the unit battery 100 is to be inserted into the pull-out tab insertion hole 215. The space between the two tapered side surfaces 222 is gradually narrowed, and attachment of the unit battery 100 to the holder member 200 is facilitated. For this reason, the work efficiency at the time of connecting the some unit battery 100 in series improves, and it can improve productivity.

  The plane sandwiched between the upper and lower two drawer tab guide protrusions 220 is such that when the drawer tab of the unit battery 100 is inserted into the drawer tab insertion hole 215, the first end 111 of the unit battery 100 abuts. It functions as an abutting portion 230 that regulates the position of the first end portion 111.

  According to such abutting portion 230, the first end portion 111 of the unit battery 100 is brought into contact with the unit battery 100, whereby the unit battery 100 can be easily aligned in the stacking direction. Work efficiency at the site increases and productivity increases.

  In the present embodiment, the abutting portion 230 has a planar shape, but the abutting portion 230 is not necessarily limited to such a shape, and the first end 111 of the unit battery 100 is not limited. Any shape is possible as long as the position can be regulated.

  Among the plurality of unit batteries 100 connected in series, for the unit batteries 100 arranged at both ends, the position of the first end 111 of the unit battery 100 cannot be regulated by the abutting part 230 as described above. However, instead of this, the unit cells 100 arranged at both ends can be aligned by applying the first end 111 to the pull-out tab guide rib 203. The surface of the drawer tab guide rib 203 with which the first end 111 abuts and the abutting portion 230 are provided on the same plane.

The substrate 300 is attached to the second surface 250 of the holder member 200. On this substrate 300, the drawer tabs of the adjacent unit cells 100 are folded and connected to achieve conduction. When connecting the drawer tabs of the adjacent unit cells 100, mechanical fixing by a connecting member such as a bolt and nut is preferable, but in the example of FIG. 4B, a nut housing for housing the nut 256 for this purpose is provided. Six portions 255 are provided on the first row 211 side on the second surface 250 side and five on the second row 212 side. In addition, on the second surface 250 side, there is a partition piece 260 for ensuring insulation between the drawer tab connecting portions of the unit cell 100 formed on the substrate 300 or between the drawer tab connecting portion and the drawer tab. Three locations are provided on the first row 211 side, and two locations are provided on the second row 212 side.

  The alignment protrusions 263 are protrusions that are used for alignment when the substrate 300 is attached to the holder member 200, and are arranged one on each of the first row 211 side and the second row 212 side. In addition, the screw holes 270 used for fixing the substrate 300 and the holder member 200 after the substrate 300 is attached to the holder member 200 by using the alignment projection 263 described above are provided on the first row 211 side. And one on each of the second row 212 side. Here, an example in which a bolt and a nut are used as the connecting member is shown, but a connecting member such as a caulking pin or a rivet may be used instead of the bolt and the nut.

  FIG. 5 is a perspective view of a holder member 200 used in configuring the battery pack according to the embodiment of the present invention. Eight pull-out tab insertion holes 215 are provided in the first row 211 of the second surface 250 of the holder member 200, and eight pull-out tab insertion holes 215 in the second row 212, respectively. The structure between the two is integrally formed with the main body using the same resin as the main body, and this structure is referred to as a bridging structure portion 251.

  In the present embodiment, it is one of the major features that various functionalities are imparted to the bridging structure portion 251.

  For example, in the bridging structure portion 251 shown in FIG. 5A, the bridging structure portion 251 is provided with a nut accommodating portion 255 that accommodates the nut 256. Such a bridging structure portion 251 is effective for strengthening the rigidity of the holder member 200, can provide a space for accommodating the nut 256, and can effectively utilize the space.

  In addition, for example, in the bridging structure portion 251 shown in FIG. 5B, a partition piece 260 is provided between the connecting portions of the drawer tabs. Such a bridging structure portion 251 is effective for strengthening the rigidity of the holder member 200, and can provide a space for standing the partition piece 260, so that the space can be effectively used.

  Further, for example, in the bridging structure portion 251 shown in FIG. 5C, an alignment projection 263 used for alignment between the substrate 300 and the holder member 200 is provided. Such a bridging structure portion 251 is effective for strengthening the rigidity of the holder member 200, and can provide a space for standing the alignment projection 263, so that the space can be effectively used.

  Further, for example, in the bridging structure portion 251 shown in FIG. 5D, a screw hole 270 into which the board fixing screw 271 for fixing the board 300 and the holder member 200 is screwed is provided. Such a bridging structure portion 251 is effective for strengthening the rigidity of the holder member 200, and can provide a space for the screw hole 270, thereby effectively utilizing the space.

  Next, in the battery pack according to the embodiment of the present invention, the configuration of the substrate 300 on which the connecting portions of the drawer tabs of the plurality of unit cells 100 are formed will be described. FIG. 6 is a perspective view of a substrate 300 used in series connection of unit batteries 100 in the battery pack according to the embodiment of the present invention.

The substrate 300 mainly composed of glass epoxy or the like is used by being attached to the second surface 250 side of the holder member 200, and the outer peripheral shape of the substrate 300 is
The holder member 200 substantially conforms to the outer peripheral shape on the second surface 250 side. At two locations on the outer periphery of the substrate 300, drawer tab drawing notches 314 are formed so as to correspond to the drawer tab drawing recesses 214 of the holder member 200.

  The substrate 300 is provided with a pull-out tab lead-out hole 315 so as to correspond to the pull-out tab insertion hole 215 of the holder member 200. In addition, the substrate 300 is provided with partition piece extraction holes 317 so as to correspond to the partition pieces 260 of the holder member 200. In addition, the substrate 300 is provided with drawer tab / partition piece extraction holes 316 corresponding to both the drawer tab insertion holes 215 and the partition pieces 260 of the holder member 200. Each of these holes is a hole penetrating from one main surface of the substrate 300 to the other main surface, and is configured such that a drawer tab of the unit battery 100, a partition piece 260, and the like can be inserted.

  A thin film electrode portion 320a, a thin film electrode portion 320b, and a thin film electrode portion 320c are provided at a location where the drawer tab of the unit battery 100 is fixed to the substrate 300 with a connecting member. The connecting member is preferable because the combination of the bolt and the nut is simple and can realize a strong connection, but a connecting member such as a caulking pin or a rivet may be used instead of the bolt and the nut.

  The thin film electrode portion 320 a is electrically connected to the metal positive electrode washer 321 fixed on the substrate 300, and the thin film electrode portion 320 c is connected to the metal negative electrode washer fixed on the substrate 300. Conduction with 322 is achieved. The positive electrode washer 321 and the negative electrode washer 322 are connected to the pull-out tab at the end of the unit battery 100 connected in series, so that the positive electrode washer 321 and the negative electrode washer 322 are battery packs. It will be used as a terminal for charging and discharging power.

  Further, the thin film electrode part 320 b is electrically connected to a terminal part (not shown) of the connector 340, and the potential for monitoring each unit battery 100 can be measured via the connector 340. . The connector 340 can also be configured such that a signal from a temperature measurement sensor (not shown) that measures the temperature of the unit battery 100 can be taken out.

  Further, each of the thin film electrode portion 320a, the thin film electrode portion 320b, and the thin film electrode portion 320c is provided with a drawer tab connection screw hole 325 through which a drawer tab connection bolt 257 used for fixing the drawer tab of the unit battery 100 is inserted. It has been. In the thin film electrode part 320a and the thin film electrode part 320c, one drawer tab of the unit battery 100 at the end of the unit batteries 100 connected in series is fixed. On the other hand, two thin film electrode portions 320b are fixed so that the pull-out tabs of adjacent unit cells 100 are folded.

  Two alignment holes 328 corresponding to the alignment protrusions 263 provided on the second surface 250 side of the holder member 200 are formed in the substrate 300, and the two alignment protrusions 263 are By passing through the alignment hole 328, it is possible to easily align the holder member 200 and the substrate 300, which contributes to an improvement in productivity. The substrate fixing screw hole 329 formed in the substrate 300 is a hole through which the substrate fixing screw 271 used for fixing the holder member 200 and the substrate 300 is inserted.

In the battery pack according to the present invention, not only the substrate 300 but also the holder member 200 integrated therewith is used to connect adjacent unit batteries 100 to form a series connection. According to this, the drawer tab is firmly fixed from both sides of the substrate 300 by connecting members such as bolts and nuts, and the drawer tab guide protrusion 220 on the surface opposite to the surface to which the tab of the substrate 300 is fixed. However, in order to ensure insulation between the drawer tabs of the unit battery 100, a highly reliable battery pack can be provided.

  Next, in the battery pack according to the embodiment of the present invention, when a plurality of unit batteries 100 are connected in series to form a battery connection structure 500, a battery protection member 400 for protecting this will be described. FIG. 7 is a view for explaining a battery protection member 400 used in configuring the battery pack according to the embodiment of the present invention. FIG. 7A is a flat plate portion 410 to which the main surface of the unit battery 100 is attached. FIG. 7B is a view of the battery protection member 400 as viewed from the upper side of FIG. 7A.

  The battery protection member 400 is a member formed of, for example, a synthetic resin such as ABS, and is used so as to be inserted between the stacked unit cells 100 when the unit cells 100 are stacked. The flat plate portion 410 of the battery protection member 400 is a member that is sandwiched between the unit battery 100 and the unit battery 100 connected in series therewith. On the other hand, the protect side plate portion 440 is provided so as to extend from both ends of the flat plate portion 410 in a direction perpendicular to the flat plate portion 410. Therefore, as shown in FIG. 7B, the battery protection member 400 is a member having an H-shaped cross section.

  The flat plate 410 has a first notch 421 that is the deepest notch and both sides of the first notch 421, and a second notch that is deeper than the first notch 421. A notch portion 420 is configured that includes a notch portion 422 and a third notch portion 423 that is the shallowest notch portion disposed on both sides of the second notch portion 422.

  Next, a procedure for manufacturing the battery connection structure 500 formed by connecting the unit batteries 100 from the above members will be described with reference to FIGS. 8 to 18 are views for explaining a manufacturing process of the battery connection structure 500 constituting the battery pack according to the embodiment of the present invention.

  First, in the process illustrated in FIG. 8, the nuts 256 are attached to all the nut accommodating portions 255 provided on the second surface 250 of the holder member 200. The inner circumference of the nut accommodating portion 255 is set to such a size that the nut 256 cannot be easily removed when the nut 256 is fitted into the nut accommodating portion 255.

  In the subsequent process shown in FIG. 9, the alignment projection 263 of the holder member 200 is inserted into the alignment hole 328 of the substrate 300, thereby aligning the holder member 200 and the substrate 300. Subsequently, the two board fixing screws 271 are inserted into the board fixing screw holes 329 and screwed into the screw holes 270, so that the holder member 200 and the board 300 are fixed. Note that various types of screws can be used as the board fixing screw holes 329. However, the use of tapping screws improves the working efficiency during manufacturing.

  In the process shown in FIG. 10, the unit battery 100 is disposed on the first surface 210 of the holder member 200. The alignment at this time is performed by abutting the first end 111 of the unit battery 100 against the pull-out tab guide rib 203. Next, the negative electrode lead tab 130 of the unit battery 100 is bent so as to contact the thin film electrode part 320 b of the substrate 300 using the lead tab drawing recess 214. Further, the positive electrode pull-out tab 120 of the unit battery 100 is bent so as to contact the thin film electrode portion 320 a of the substrate 300 using the pull-out tab lead-out portion 213, and the pull-out tab connection bolt 257 is inserted into the hole of the positive electrode pull-out tab 120. 127. The drawer tab connection screw hole 325 is inserted, and the drawer tab connection bolt 257 and the nut 256 accommodated in the nut accommodating portion 255 are screwed together. Thereby, the attachment of the first unit battery 100 is completed.

  The next step shown in FIG. 11 is an operation on the first surface 210 side of the holder member 200. In this step, two double-sided adhesive tapes 460 are attached to the upper main surface of the unit battery 100 as shown in the drawing. The double-sided adhesive tape 460 is used for fixing between the unit battery 100 that is first attached to the holder member 200 and the unit battery 100 that is secondly attached to the holder member 200. The double-sided adhesive tape 460 is provided on the main surface of the unit battery 100 as shown in the figure because a spacer described later is arranged between the two double-sided adhesive tapes 460 to increase productivity. is there.

  In the subsequent process shown in FIG. 12, a spacer (not shown) having a thickness equal to or larger than the thickness of the double-sided adhesive tape 460 is disposed on the unit battery 100 attached first, and further, the spacer is placed on the spacer. The two drawer tabs of the second unit battery 100 are inserted into the drawer tab insertion holes 215 so as to slide. As described above, the pull-out tab guide protrusions 220 are arranged above and below the two pull-out tab insertion holes 215. Further, since the pull-out tab guide protrusions 220 are provided with tapered side surfaces 222, The space between the pull-out tab guide protrusions 220 is gradually narrowed. Thereby, the drawer tab of the unit battery 100 can be easily guided to the drawer tab insertion hole 215 of the holder member 200.

  The abutting portion 230 between the upper and lower drawer tab guide protrusions 220 is configured such that when the drawer tabs (120, 130) of the unit battery 100 are inserted into the drawer tab insertion holes 215, the first end of the unit battery 100 is formed. The part 111 contacts and regulates the position of the first end part 111. Since the holder member 200 is provided with such an abutting portion 230, the unit battery 100 can be easily aligned in the stacking direction by bringing the first end portion 111 of the unit battery 100 into contact therewith. This can be performed, and the work efficiency in manufacturing the battery bag is increased, and the productivity is improved.

  As described above, the first end unit 111 is brought into contact with the abutting unit 230 and the spacer is removed, so that the unit battery 100 attached first and the unit battery 100 attached second are obtained. Bonding is performed using a double-sided adhesive tape 460.

  In the present embodiment, two double-sided adhesive tapes 460 are attached to the main surface of the unit battery 100 so that the unit batteries 100 are joined to each other so as to impart vibration resistance to the battery pack. However, conditions suitable for this purpose will be described below.

  FIG. 27 is a diagram for explaining the bonding conditions between the unit cells 100. FIG. 27A is a diagram showing dimensions of the unit battery 100 used in the battery pack according to the present embodiment, and FIG. 27B is used for bonding the unit battery 100 used in the battery pack according to the present embodiment. It is a figure which shows the dimension of the double-sided adhesive tape 460. FIG.

  The unit battery 100 includes a first end 111 having a length of 82 mm, a side end 113 having a length of 150 mm, and chamfered portions 119 formed at both corners of the second end 112. The outer peripheral length is 459 mm.

Here, an electrode stack region 105 in the unit battery 100 is defined. The electrode laminated region 105 is a region corresponding to a location where an electrode laminated body including a sheet-like positive electrode, a sheet-like negative electrode, and a separator, which are sealed in the unit battery 100, in the laminate film exterior material. That is, the electrode lamination region 105 is a main plane region corresponding to a location where the laminate film exterior material swells by accommodating the electrode laminate. In the perspective view of the unit battery 100 of FIG. The electrode lamination region 105 has a substantially rectangular shape, but its long side is 131 mm, its short side is 69 mm, and the electrode lamination region 105 has an outer peripheral length of 400 mm.

  Further, when the battery pack according to the present embodiment is configured, the dimensions of the double-sided adhesive tape 460 used for bonding the unit batteries 100 are 100 mm for the long side and 12 mm for the short side, The outer peripheral length of one double-sided adhesive tape 460 is 224 mm. In the present embodiment, since two double-sided adhesive tapes 460 are used, the total outer peripheral length of the double-sided adhesive tape 460 used for joining the batteries is 448 mm.

  Here, the total outer peripheral length of the double-sided adhesive tape 460 is set to be longer than the outer peripheral length of the electrode laminated region 105 which is a region corresponding to the location where the electrode laminated body is accommodated in the laminate film exterior material. There is a point. When a vibration test was performed with such settings, good results could be obtained.

  According to the battery pack according to the present invention as described above, the total outer peripheral length of the double-sided adhesive tape 460 is the region of the electrode laminated region 105 which is a region corresponding to the accommodation location of the electrode laminated body in the laminated film exterior material of the unit battery 100. Since it is set to be longer than the outer peripheral length, even if vibration is applied, the unit cells are not separated from each other, and stress is not applied to the connecting portion between the drawer tabs, so that reliability is improved. It can be done. In addition, since the stresses generated at the ends of the double-sided adhesive tape can be dispersed as compared with the case where the batteries are bonded most strongly, that is, compared to the case where the entire surface corresponding to the accommodation location of the electrode laminate is bonded Even if vibration is applied to the pack, the laminate film exterior material can be hardly damaged.

  In this embodiment, two double-sided adhesive tapes 460 are used in order to satisfy the above conditions, but the total outer peripheral length of the double-sided adhesive tape 460 is the laminate film of the unit battery 100. The shape of the double-sided adhesive tape 460 is not limited to this as long as it is set to be longer than the outer peripheral length of the electrode laminated region 105 in the exterior material. For example, by providing a plurality of circular patch-like double-sided adhesive tapes, it is possible to increase the total outer peripheral length, satisfy the above conditions, and improve the manufacturability. Hereinafter, other shape examples of the double-sided adhesive tape 460 will be described.

  FIG. 28 is a diagram for explaining another example of the bonding condition between the unit cells 100. FIG. 28A is a diagram showing dimensions of the unit battery 100 used in the battery pack according to the present embodiment, and FIG. 28B is used for bonding the unit battery 100 used in the battery pack according to the present embodiment. It is a figure which shows the dimension of the double-sided adhesive tape 460. FIG. The dimensions of the unit battery 100 itself are the same as those shown in FIG.

  In the example of FIG. 28, when forming the battery pack, the double-sided adhesive tape 460 used for bonding the unit batteries 100 has a long side length of 100 mm and a short side length of 6 mm. The outer peripheral length of the double-sided adhesive tape 460 is 212 mm. In the example of FIG. 28, since the double-sided adhesive tape 460 is used in three strips, the total outer peripheral length of the double-sided adhesive tape 460 used for joining the batteries is 636 mm, and can be set longer than the outer peripheral length 400 mm of the electrode lamination region 105. . As described above, the same effect as that of the previous embodiment can be obtained also by the bonding condition as shown in FIG.

  FIG. 29 is a diagram for explaining another example of the bonding condition between the unit cells 100. FIG. 29A is a diagram showing dimensions of the unit battery 100 used in the battery pack according to the present embodiment, and FIG. 29B is used for bonding the unit battery 100 used in the battery pack according to the present embodiment. It is a figure which shows the dimension of the double-sided adhesive tape 460. FIG. The dimensions of the unit battery 100 itself are the same as those shown in FIG.

  In the example of FIG. 29, when the battery pack is configured, the double-sided adhesive tape 460 used for bonding the unit batteries 100 is a circular shape having a diameter of 30 mm, and the outer peripheral length is about 94.2 mm. is there. In the example of FIG. 29, since six of such circular double-sided adhesive tapes 460 are used, the total outer peripheral length of the double-sided adhesive tape 460 used for joining the batteries is 565.2 mm, and the outer peripheral length of the electrode lamination region 105 is 400 mm. It can be set longer. As described above, the same effect as that of the previous embodiment can be obtained also by the bonding condition as shown in FIG.

  Next, the bonding strength suitable for bonding the unit cells 100 with the double-sided adhesive tape 460 will be described. Here, the description will be given using the dimensional relationship of FIG.

Since the adhesive strength of the double-sided tape 460 used in this embodiment is 0.98 N / mm, two strips of double-sided tape 460 having a long side length of 100 mm and a short side length of 12 mm are used. Accordingly, the bonding strength (tensile strength) between the unit cells 100 in the long side direction and the short side direction is as follows.
Long side direction: 0.98 (N / mm) × 12 (mm) × 2 (pieces) = 24N
Short side direction: 0.98 (N / mm) × 100 (mm) × 2 (pieces) = 98N
On the other hand, the adhesive strength of the fused part of the laminate film exterior material of the unit battery 100 is 1.5 N / mm. In the unit battery 100 shown in FIG. 27, the narrowest width fused portion is 5 mm. From the above, the minimum bonding strength of the fused portion of the laminated film exterior material of the unit battery 100 is as follows in the long side direction and the short side direction.
Long side direction: 1.5 (N / mm) × 5 (mm) × 2 (side) = 15N
Short side direction: 1.5 (N / mm) × 5 (mm) × 2 (pieces) = 15N
Moreover, the maximum joining strength of the fusion | melting part of the laminate film exterior material of the unit battery 100 is as follows in a long side direction and a short side direction.
Long side direction: 1.5 (N / mm) × 82 (mm) = 123N
Short side direction: 1.5 (N / mm) × 150 (mm) = 225N
In the present embodiment, the bonding strength between the unit cells 100 by the double-sided adhesive tape 460 is set to be larger than the minimum bonding strength of the fused portion. According to this, when the battery pack is disassembled and the unit battery 100 is taken out, the unit battery 100 becomes unusable because the fused portion of the unit battery 100 is peeled off. The risk of being reused can be prevented.

  Here, the positive electrode extraction tab 120 of the unit battery 100 that is first attached to the holder member 200 is arranged on the first row 211 side, and the negative electrode extraction tab 130 is arranged on the second row 212 side. The unit cell 100 that is second attached to the holder member 200 is arranged such that the positive electrode extraction tab 120 is on the second row 212 side and the negative electrode extraction tab 130 is on the first row 211 side. Hereinafter, when the unit cells 100 are sequentially stacked, the positive lead tabs 120 of the odd-numbered unit cells 100 are arranged on the first row 211 side, and the negative lead tabs 130 are arranged on the second row 212 side. The positive lead tabs 120 of the unit cells 100 that are evenly attached are arranged on the second row 212 side, and the negative lead tabs 130 are arranged on the first row 211 side. As described above, since the orientation of the pull-out tabs of the adjacent unit cells 100 is different in the stacking direction, it is not necessary to make an oblique connection in the stacking direction on the substrate 300 side.

  After confirming that the first end portion 111 of the second unit battery 100 is pushed in until it abuts against the first surface 210 of the holder member 200, the operation proceeds to the next operation on the substrate 300 side.

In the subsequent step shown in FIG. 13, the positive electrode pull-out tab 120 of the unit battery 100 attached second is bent downward in the figure and overlapped with the negative electrode pull-out tab 130 of the unit battery 100 attached first. . Then, the drawer tab connection bolt 257 is inserted into the hole / drawer tab connection screw hole 325 of each drawer tab, and the drawer tab connection bolt 257 and the nut 256 are screwed together to form the thin film electrode portion 320b. A connection portion between the negative electrode pull-out tab 130 of the unit battery 100 attached first and the positive electrode pull-out tab 120 of the unit battery 100 attached second is formed, and the electrical connection is completed.

  On the other hand, the negative electrode pull-out tab 130 of the unit battery 100 attached second is bent upward in the drawing to prepare for connection with the positive electrode pull-out tab 120 of the unit battery 100 attached third.

  In the process shown in FIG. 14, the battery protection member 400 is attached using a spacer in the same manner as when the second unit battery 100 is attached. The upper surface of the second unit battery 100 and the lower surface of the battery protection member 400 are attached by two double-sided adhesive tapes 460. Further, as shown in the drawing, two double-sided adhesive tapes 460 are attached to the upper surface of the battery protection member 400. With this double-sided adhesive tape 460, the battery protection member 400 and the unit battery 100 that is thirdly attached to the holder member 200 are joined.

  The battery protection member 400 is attached to the unit battery 100 with a gap of about 2 mm between the second notch 422 or the third notch 423 and the holder member 200. This gap makes it difficult for vibrations and shocks applied to the battery pack to be transmitted to the positive electrode extraction tab 120 and the negative electrode extraction tab 130, thereby improving the reliability of the electrical connection of the battery pack.

  Note that this gap is not necessarily provided when it is expected that vibration or impact applied to the battery pack is small. In this case, the battery protection member 400 can be attached to the unit battery 100 in a state where the battery protection member 400 is pushed in until the second notch 422 or the third notch 423 hits the holder member 200. By attaching in this way, the battery protective member 400 can be easily aligned in the stacking direction.

  FIG. 15 shows a state in which the third unit battery 100 to the eighth unit battery 100 are sequentially attached to the holder member 200 and the substrate 300 by the same method as described above. On the substrate 300 side, each time the unit cells 100 are attached one by one, the drawer tab is folded, and the drawer tab connection bolts 257 are used to connect the drawer tabs of adjacent unit cells 100 to make electrical connection. Go.

  The next step shown in FIG. 16 shows a state in which the battery protection member 400 is further attached after the eighth unit battery 100 is attached. As described above, in the battery connection structure 500 according to the present embodiment, the two battery protection members 400 are arranged, thereby protecting each unit battery 100 from an external impact or the like. .

  FIG. 17 shows a state in which the ninth unit battery 100 and the tenth unit battery 100 are further attached to the holder member 200 and the substrate 300 on the battery protection member 400. The negative electrode pull-out tab 130 of the tenth unit cell 100 is bent using the pull-out tab lead-out portion 213 so as to contact the thin-film electrode portion 320c of the substrate 300, and the thin-film electrode portion by the pull-out tab connection bolt 257. It adheres to 320c. Accordingly, the drawer tabs of the first to tenth unit cells 100 are connected on the substrate 300, and the series connection of the ten unit cells 100 is completed. Charging / discharging the ten unit cells 100 connected in series can be performed using the electrode washer 321 for positive electrode and the electrode washer 322 for negative electrode. A terminal member 331 is attached to the positive electrode washer 321, and a terminal member 332 is attached to the negative electrode washer 322, thereby completing the battery connection structure 500.

  As described above, according to the battery pack of the present invention, the operation of inserting the positive electrode pull-out tab and the negative electrode pull-out tab of the plurality of unit batteries 100 into the pull-out tab insertion hole 215 of the holder member 200 is performed. Since the drawer tabs having different polarities of the battery 100 are connected to each other on the substrate 300, the work efficiency in manufacturing the battery bag is high, and the productivity is improved.

  In addition, since the plurality of unit cells 100 are configured such that the drawer tabs having different polarities are coupled to each other on the substrate 300 by the drawer tab connection bolts 257 and nuts 256, the plurality of unit cells 100 can be easily electrically connected. This increases the work efficiency in manufacturing the battery pack and improves the productivity.

  The feature point of each connection part of the battery connection structure 500 configured as described above will be described in more detail.

  The substrate 300 is provided with a thin film electrode part 320a, a thin film electrode part 320b, and a thin film electrode part 320c as three kinds of thin film electrode parts.

  Among these, the thin-film electrode part 320 a conducts the positive electrode washer 321 provided at one end of the substrate 300 and the positive electrode extraction tab 120 of the unit cell 100 attached to one end of the substrate 300. Used to connect. That is, the connection part in the thin film electrode part 320a functions as a positive electrode lead tab-positive electrode washer connection part.

Further, the unit battery 100 attached to one end of the substrate 300 is bent in the same direction in both the positive electrode extraction tab 120 and the negative electrode extraction tab 130 as can be seen by referring to the bending direction b ₁ in FIG. It is supposed to be.

  The thin film electrode portion 320c includes a negative electrode washer 322 provided at the other end different from the one end of the substrate 300, and a negative electrode lead tab 130 of the unit cell 100 attached to the other end of the substrate 300. Is used for conductive connection. That is, the connection part in the thin film electrode part 320a functions as a negative electrode extraction tab-negative electrode washer connection part.

The unit battery 100 is attached to the other end of the substrate 300 also, as can be seen with reference to such direction b ₂ folded in FIG. 18, from its cathode pulled-out tab 120 and the anode lead-out tab 130, folded together in the same direction It is supposed to be.

  The thin-film electrode part 320b is used to conductively connect the positive electrode extraction tab 120 of one unit cell 100 and the negative electrode extraction tab 130 of the other unit cell 100 that are not attached to both ends of the substrate 300. . That is, the connection part in the thin film electrode part 320b functions as a pull-out tab connection part that connects the pull-out tabs of the plurality of unit cells 100 having different polarities.

The unit battery 100 that is not attached to both ends of the substrate 300 and to which the drawer tab is coupled by the drawer tab coupling portion can be understood by referring to the bending directions b ₁ and b ₂ in FIG. In addition, the positive electrode extraction tab 120 and the negative electrode extraction tab 130 are bent in opposite directions.

Next, the feature point of the partition piece 260 in the battery connection structure 500 configured as described above will be described. For example, as shown in FIG. 13, the height h ₁ of the partition piece 260 from the substrate 300 is the pull-out tab (1) at the connecting portion of the pull-out tabs (120, 130).
20 and 130) are configured to be higher than the height h ₂ of the pull-out tab connection bolt 257 used for the connection. Such a dimensional relationship is established not only at the positions shown in FIG. 13 but also at the heights of all the partition pieces 260 and the heights of the pull-out tab connection bolts 257 at all the connecting portions.

Since it is configured as described above, for example, even when a conductive member approaches the substrate 300 of the battery connection structure 500, it is blocked by the partition piece 260, thereby connecting the drawer tabs of adjacent connection portions. bolt 257 with each other (e.g., pulled-out tab connection bolt 257, the drawer in the pulled-out tab connection bolt 257, C ₄ in pulled-out tab connection bolt 257 to each other. Alternatively connecting part C ₃ of the connecting portion C ₂ tabs at the junction C ₁ shown in FIG. 18 Connection bolts 257 and the like) are not short-circuited by the conductive member.

  In addition to the above effects, there are the following effects. When manufacturing the battery connection structure 500, the drawer tabs (120, 130) of the unit battery 100 are inserted through the drawer tab insertion holes 215 and attached, and the drawer tabs (120, 130) are bent on the substrate 300 side. However, since the partition piece 260 is present, there is no possibility of making a manufacturing error that causes the drawer tabs (120, 130) to be bent in a direction opposite to the direction in which the drawer tabs should be bent. In addition, even if the drawer tabs (120, 130) are bent in the direction opposite to the direction in which they should be bent, the tabs may extend over the partition piece 260 and reach the connecting portion that is not the original connecting portion. The lengths of the drawer tabs (120, 130) and the height of the partitioning pieces 260 are defined so as to be impossible, so that unintentional conduction can be avoided.

  Next, a process of forming a battery pack according to the present invention using the battery connection structure 500 configured as described above will be described with reference to FIGS. 19 to 26.

  In the process illustrated in FIG. 19, the discharge terminal mounting recess 611 and the charge terminal mounting recess 612 provided in the first case body 600 are used for the first case body 600 for housing the battery connection structure 500. Then, the discharge terminal 613 and the charge terminal 614 are screwed.

  In the process shown in FIG. 20, the first buffer member 621 is attached to the second housing portion 602 of the first case body 600, and the second buffer member 622 is attached to the circuit housing portion 603 with an adhesive or the like.

  In the step shown in FIG. 21, the third buffer member 663 is attached to the second housing portion 662 of the second case body 660 with an adhesive or the like.

  The process shown in FIG.22 and FIG.23 performs the process of attaching a shock absorbing material with respect to the battery connection structure 500. FIG. In the battery pack according to the present invention, the first battery connection structure 500 and the second battery connection structure 500 are configured to be accommodated in the battery pack. The first battery connection structure 500 and the second battery connection structure 500 are used in parallel connection.

  In the process of FIG. 22, a thick fourth buffer member 504 is attached to the unit battery 100 at the end with respect to the first battery connection structure 500, and the fourth buffer member 504 is attached to all the protect side plates. A thinner fifth buffer member 505 is attached. An adhesive or the like is used when attaching the fourth buffer member 504 and the fifth buffer member 505 to each part. Here, the thermistor 530 (not shown in FIG. 22) of the temperature detection means in the battery pack is attached only to the first battery connection structure 500. The thermistor 530 detects the temperature of the first battery connection structure 500 and transmits the detection signal to the protection circuit board 700.

  On the other hand, in the step of FIG. 23, the fourth buffer member 504 is attached to the unit battery 100 at the end with respect to the second battery connection structure 500, and the fifth buffer member is provided only on the protect side plate portion on one side. 505 is attached. As before, an adhesive or the like is used when attaching the fourth buffer member 504 and the fifth buffer member 505 to each part.

  24, the discharge terminal 613, the charge terminal 614, the thermistor 530, and the protection circuit board 700 are connected, and the protection circuit board 700 is screwed to the circuit housing portion 603 of the first case body 600. The

  In the process shown in FIG. 25, the first and second battery connection structures 500 and the protection circuit board 700 are connected, and the first and second battery connection structures are connected to the first housing portion 601 of the first case body 600. The second battery connection structure 500 is housed in the body 500 and the second housing portion 602, respectively.

  In the process shown in FIG. 26, the first case body 600 and the second case body 660 are screwed together to complete the battery pack 800 according to the present invention.

  Here, the temperature detection means in the battery pack 800 according to the present invention will be described. As described above, the battery pack 800 according to the present invention is configured by housing two battery connection structures 500 in the same case bodies 600 and 660, as shown in FIG. Of the two battery connection structures 500, the thermistor 530 is provided only in the first battery connection structure 500 housed in the first housing portion of the case body, and temperature data detected here. Is transmitted to a circuit provided on the protection circuit board 700 and used for battery control.

  The reason why the thermistor 530 is provided on the first battery connection structure 500 out of the two battery connection structures 500 accommodated in the case body is that the battery pack 800 is used in the posture in which the battery pack 800 is used. This is because the structure 500 is arranged in a vertically upward direction and is in an environment where the temperature rises more easily than the second battery connection structure 500 arranged below. FIG. 30 is a view showing a posture when the battery pack 800 according to the embodiment of the present invention is used as a power source of a bicycle.

  In the battery pack 800 according to the present invention, the thermistor 530 is attached to the first battery connection structure 500, which is disposed vertically above the case body, is more easily heated, and is in a thermally disadvantageous condition. Temperature data is acquired from the thermistor 530, and the protection circuit board 700 controls discharge stop and the like based on the temperature data. According to such a battery pack 800 according to the present invention, the number of components can be reduced, the cost can be reduced, and the circuit configuration for processing the detection data of the thermistor 530 is simplified.

  In the present embodiment, the thermistor 530 is provided in the battery connection structure 500 that is vertically above the two battery connection structures 500 provided in the case body. However, the battery connection provided in the case body is used. The present invention can be applied even when there are three or more structures 500. That is, in the case of three or more battery connection structures 500 accommodated in the case body of the battery pack, the thermistor 530 is provided only in the battery connection structure 500 that is disposed at the uppermost position when used. To do.

Next, the vibration resistance of the battery pack 800 configured as described above will be described. In battery packs constructed by laminating unit cells using a laminate sheathing material while being connected in series, the corners of the laminate film sheathing material of the unit cell are laminated to the adjacent unit cell when subjected to vibration. There was a problem that the battery pack breaks down, leaks out the electrolyte solution and the like, and the battery pack breaks down. In order to solve such problems, it is conceivable to chamfer all corners of the laminate film of the unit cell, but chamfering all corners increases the manufacturing process and increases the manufacturing cost. Problems will occur.

  Therefore, in the present invention, reliability is improved from the viewpoint of vibration resistance while minimizing the corners for chamfering. Hereinafter, the configuration for this will be described with reference to FIG. 1 again.

  The battery body 110 is sealed by heat-sealing the outer periphery of the laminate film exterior material in a state in which the electrode laminate having the sheet-like positive electrode, the sheet-like negative electrode, and the separator and the electrolytic solution are housed inside. Has been. A positive electrode extraction tab 120 and a negative electrode extraction tab 130 are extracted from the first end 111 side in the outer periphery.

  Here, in the laminate film exterior material, the dimensional relationship of the fused part formed by heat sealing will be considered. Here, the fused portion indicated by c formed on the first end 111 side is the first fused portion 117, and the fused portion indicated by d formed on the second end 112 side is the second. This is defined as a fused portion 118. All the fused portions are indicated by oblique lines in the figure. Further, the fusion weld lengths of the first fusion part 117 and the second fusion part 118 are both defined by the length in the pull-out direction of the tab.

  In the unit battery 100 used in the present embodiment, the second fusion welding length d of the second fusion bonding portion 118 is set shorter than the first fusion welding length c of the first fusion fusion portion 117. In the case where the unit battery 100 is used by being laminated, even if the corner of the laminated film exterior material of the adjacent unit battery 100 is rubbed against the first fusion part 117, the probability that the first fusion part 117 is torn is extremely high. On the other hand, when the corner of the laminated film exterior material of the adjacent unit battery 100 is rubbed against the second fusion part 118, the probability that the second fusion part 118 is broken becomes large to some extent.

  Therefore, in the present embodiment, chamfering is performed on the two second end side corner portions 116 in the second end portion 112, and chamfered portions 119 are formed at both corner portions. Accordingly, even when vibration is applied to the battery pack 800, the second end side corner portion 116 in which the chamfered portion 119 is formed does not affect the second fused portion 118 of the adjacent unit battery 100. The leakage of the electrolyte does not occur and the reliability can be improved.

  On the other hand, even if the first end portion 111 is rubbed against the first end corner portion 115 of the laminated film exterior material of the adjacent unit battery 100 due to vibration applied to the battery pack 800, the first fusion portion Since the probability that 117 is broken is very low, an increase in the number of manufacturing steps is suppressed without forming chamfers at the two first end corners 115 on the first end 111 side.

  Here, a dimensional relationship between the first fusion welding length c and the second fusion welding length d, which is more preferable in manufacturing the battery pack according to the present invention, will be described below.

  In the unit battery 100 used in the present embodiment, the first fusion length c is 19 ± 1 mm, and the second fusion length d is 6 ± 1 mm. In any fusion welding length, “± 1 mm” is a manufacturing error. The dimensions of the fusion welding length as described above are determined on the basis of the following.

  First, in any fusion part of the unit battery 100, the fusion width is desirably 5 mm or more in order to ensure the sealing property of the laminate film exterior material.

  The second fusion length d, which is the fusion width in the second fusion part 118, is set to 6 ± 1 mm in consideration of manufacturing tolerances and the like while giving a margin.

  In addition, when the first fusion welding length c, which is the fusion welding width in the first fusion part 117, is about 18 mm or more, when the battery pack is configured, the first end side corner 115 of the adjacent unit battery 100 hits. Even if it is rubbed, the probability that the first fusion part 117 is broken can be made extremely low, and the reliability of the battery pack can be improved. Therefore, in the unit battery 100 according to the present embodiment, the first fusion welding length c is set to 19 ± 1 mm in consideration of manufacturing tolerances and the like while giving a margin.

  From the above, in order to define the dimensional relationship between the first fusion welding length c and the second fusion welding length d, c / d is a value obtained by dividing the first fusion welding length c by the second fusion welding length d. When the value is calculated, c / d = (19 ± 1) / (6 ± 1). Since this c / d value is preferably a predetermined value or more than the worst condition value, it is preferable that c / d ≧ (19−1) / (6 + 1) ≈2.5. That is, in the battery pack according to the present invention, it is preferable that the c / d value obtained by dividing the first fusion welding length c by the second fusion welding length d is 2.5 or more.

  The battery pack 800 according to the present invention as described above has a configuration in which the chamfered portions 119 are provided at both corners on the second end portion 112 side where the fusion welding length is short, and an increase in the manufacturing process is suppressed at the manufacturing stage. On the other hand, in actual use, even when exposed to vibration, the laminated film of the adjacent unit battery 100 is not pierced, and no leakage of the electrolyte occurs, so that the reliability can be improved. is there.

  In the present embodiment, when the two second end side corners 116 of the second end portion 112 are chamfered, the chamfered portion 119 is formed by cutting it into a straight line. The chamfered portion 119 having R may be formed by cutting the end-side corner portion 116 into an arc shape.

  Further, in the present embodiment, the example of the unit battery 100 in which the fusion parts are provided on all four sides of the laminate film exterior material has been described. However, the present invention is not limited to such a unit battery 100, and the laminate film exterior is provided. The present invention can also be applied to a material in which fused portions are provided on three sides of the material. Such a unit battery 100 will be described with reference to FIG.

  FIG. 31 is a diagram showing another example of the unit battery 100 that constitutes the battery pack 800. The battery main body 110 of the unit battery 100 shown in FIG. 31 includes an electrode laminate in which a plurality of sheet-like positive electrodes and a plurality of sheet-like negative electrodes are laminated via a separator, and an electrolyte solution (both not shown) are laminated. The laminated film exterior material is folded at the second end 112 and is welded on a total of three sides of the first end 111 and the two side ends 113. The electrode laminate and the electrolytic solution are enclosed in the laminate film exterior material.

  Even when such a unit battery 100 is used, the two second end corners 116 at the second end 112 are chamfered, and the chamfered portions 119 are formed at both corners. You can enjoy the same effect.

More specifically, the positive electrode extraction tab 120 and the negative electrode extraction tab 130, the first end portion 111 from which the positive electrode extraction tab 120 and the negative electrode extraction tab 130 are extracted, and the first end portion 111 are opposed to each other and fusion bonding is performed. The second end portion 112 that is not performed, the first fusion portion 117 having a first fusion welding length in the tab pull-out direction on the first end portion 111 side, and both the second end portions on the second end portion 112 A battery pack in which a plurality of unit batteries 100 each having a laminated exterior member provided with a chamfered portion 119 at the corner portion 116 are connected in series can also enjoy the same effect as the above case. That is, according to this, even if vibration is applied to the battery pack 800, the second end side corner portion 116 in which the chamfered portion 119 is formed does not affect the adjacent unit battery 100, and the electrolyte leaks out. Thus, a highly reliable battery pack 800 can be provided.

DESCRIPTION OF SYMBOLS 100 ... Unit battery, 105 ... Electrode lamination | stacking area | region, 110 ... Battery main-body part, 111 ... 1st edge part, 112 ... 2nd edge part, 113 ... Side edge part, 115 ... 1st end side corner, 116 ... 2nd end side corner, 117 ... 1st fusion part, 118 ... 2nd fusion part, 119 ... Chamfering part, 120 ..Positive electrode pull-out tab, 125 ... additional tab member, 127 ... hole, 130 ... negative electrode pull-out tab, 137 ... hole, 200 ... holder member, 203 ... drawing tab guide rib, 210 ... first surface, 211 ... first row, 212 ... second row, 213 ... drawing tab routing portion, 214 ... drawing tab routing recess, 215 ... drawing tab Insertion hole, 220 ... Drawing tab guide protrusion, 221 ... Top, 222 ... Te Par side surface, 230 ... Abutting portion, 250 ... Second surface, 251 ... Bridge structure portion, 255 ... Nut receiving portion, 256 ... Nut, 257 ... Drawer tab connecting bolt, 260 ... partitioning piece, 263 ... positioning protrusion, 270 ... screw hole, 271 ... board fixing screw, 300 ... board, 314 ... drawer tab drawing notch, 315 ... Drawer tab lead-out hole, 316 ... Drawer tab / partition piece lead-out hole, 317 ... Partition piece lead-out hole, 320a, 320b, 320c ... Thin film electrode part, 321 ... Electrode washer for positive electrode, 322... Electrode washer for negative electrode, 325... Extraction tab connection screw hole, 328 .. alignment hole, 329 .. board fixing screw hole, 331, 332... Terminal member, 340. 4 DESCRIPTION OF SYMBOLS 0 ... Battery protection member, 410 ... Flat plate part, 420 ... Notch part, 421 ... 1st notch part, 422 ... 2nd notch part, 423 ... 3rd notch part, 440 ... Protect side plate part, 460 ... Double-sided adhesive tape, 500 ... Battery connection structure, 504 ... Fourth buffer member (thickness), 505 ... Fifth buffer member (thin), 530 ..Thermistor, 600... First case body, 601... First housing portion, 602... Second housing portion, 603... Circuit housing portion, 611. ··· charging terminal mounting recess, 613 ··· discharge terminal, 614 ··· charging terminal, 621 ··· first buffer member, 622 ··· second buffer member, 660 ··· second case body, 661 .. First housing part, 662... Second housing part, 663... Third buffer member, 67 3 ... Circuit housing part, 700 ... Protection circuit board, 800 ... Battery pack

Claims (3)

A plurality of unit cells each having a positive electrode extraction tab and a negative electrode extraction tab;
A substrate on which a drawer tab connecting portion to which drawer tabs of different polarities of adjacent unit cells are connected to each other is formed;
A battery pack, comprising: a holder member fixed to the substrate and having a hole through which the positive electrode extraction tab and the negative electrode extraction tab of the plurality of unit cells are inserted. The battery pack according to claim 1, wherein the holder member is provided with a guide protrusion so as to sandwich the hole. The battery pack according to claim 2, wherein the guide protrusion has a tapered side surface.

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