JP2022105020A - Connection module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a connection module capable of improving assembling workability.

SOLUTION: A connection module 1 comprises: an FPC 20; a plurality of bus bars 10 that are connected to the FPC 20 and connect adjacent electrode terminals 91A and 91B of a power storage element 90 to each other; and a resin protector 40 that holds the bus bars 10 and the FPC 20. The FPC 20 comprises: an FPC main body 21; and first moving parts 31 that connect the FPC main body 21 and the bus bars 10. The resin protector 40 comprises: a plurality of FPC holding parts 41 to which the FPC main body 21 is fixed; a movable bus bar holding part 61 to which the bus bars 10 are fixed; and a plurality of second moving parts 51 that connect the FPC holding parts 41 and the movable bus bar holding part 61. The first moving parts 31 and the second moving parts 51 connect the bus bars 10 and the movable bus bar holding part 61 while allowing displacement with respect to the FPC main body 21 and the FPC holding parts 41.

SELECTED DRAWING: Figure 1

COPYRIGHT: (C)2022,JPO&INPIT

Description

The techniques disclosed herein relate to connection modules.

A battery module for an electric vehicle or a hybrid vehicle includes a battery block composed of a plurality of battery cells and a connection module attached to the battery block to connect a plurality of single batteries. As a connection module, a flexible printed wiring board with a bus bar including a flexible printed circuit board (FPC) and a plurality of bus bars connected to the flexible printed circuit board and connecting the electrode terminals of adjacent power storage elements is known (patented). See Document 1).

Japanese Unexamined Patent Publication No. 2014-86246

A battery block composed of a large number of battery cells has a dimensional tolerance due to a manufacturing dimensional error of each battery cell, an assembly error of a plurality of battery cells, and the like. Due to this dimensional tolerance, a positional shift may occur between the bus bar and the electrodes of each battery cell, making it difficult to assemble the connection module to the battery block. Further, since the flexible printed wiring board has flexibility, it is difficult to handle when assembling to the battery block, and there is a problem that the assembling workability is poor.

The connection module disclosed in the present specification is a connection module attached to a power storage element group composed of a plurality of power storage elements including electrode terminals to connect the plurality of power storage elements, and is a flexible printed circuit board and the said. The flexible printed circuit board is provided with a plurality of connecting members connected to the flexible printed circuit board to connect the electrode terminals of the power storage elements adjacent to each other, and a holding member for holding the plurality of connecting members and the flexible printed circuit board. The substrate includes a substrate main body and a first movable portion that connects the substrate main body and the connection member, and the holding member is fixed to a substrate holding portion to which the substrate main body is fixed and the connection member is fixed. A connection member holding portion to be formed, and a second movable portion for connecting the substrate holding portion and the connecting member holding portion are provided, and the first movable portion and the second movable portion are the connecting member. The connecting member holding portion is connected to the substrate main body and the substrate holding portion while allowing displacement.

According to the above configuration, since the connecting member and the connecting member holding portion are allowed to be displaced with respect to the substrate main body and the substrate holding portion in a state of being assembled with each other, the electrode is caused by the dimensional tolerance of the power storage element group. It is possible to avoid difficulty in assembling the connection module to the power storage element group due to the displacement of the terminals, and improve the assembling workability. Further, by holding the flexible printed circuit board and the plurality of connecting members in the holding member, the shape of the flexible printed circuit board having flexibility is kept constant, and the storage element group is predetermined together with the plurality of connecting members. Since it can be set in the position, the assembly workability can be improved.

In the above configuration, the first movable portion may include a wire spring-shaped first spring portion extending from the substrate main body and having at least one curved portion.

According to such a configuration, the connecting member can be connected to the substrate main body while allowing displacement with a simple configuration. Further, by forming the first spring portion with a wire spring, the connecting member is free to some extent in any of the directions of proximity to and away from the substrate body, the thickness direction of the substrate body, and the direction along the substrate body. Since it can be displaced to, it is possible to easily perform the assembling work when assembling to the holding member after connecting the connecting member to the flexible printed circuit board.

In the above configuration, the plurality of the second movable portions are arranged side by side along one edge of the substrate holding portion, and each of the plurality of the second movable portions expands and contracts in a direction along the one edge. It may be provided with a possible second spring portion.

According to such a configuration, the second spring portion allows the displacement of the connecting member holding portion in the direction along one edge of the substrate holding portion. Therefore, by assembling the connection module to the power storage element group so that one edge of the substrate holding part extends along the arrangement direction of the plurality of power storage elements, the connection member holding part and the connection held by the connection member holding part. Displacement of the member in the direction along the arrangement direction of the power storage element group is allowed. As a result, it is possible to prevent the connection module from being difficult to assemble to the power storage element group due to the positional deviation of the electrode terminals due to the dimensional tolerance of the power storage element group, and to improve the assembly workability.

Further, the holding member may include a connecting portion that connects adjacent connecting member holding portions while allowing displacement in a direction along the one edge.

According to such a configuration, the adjacent connecting member holding portions are connected to each other without hindering the displacement of the connecting member holding portion in the direction along the arrangement direction of the power storage element group, and a plurality of connecting members are stably held. be able to.

In the above configuration, the substrate holding portion is arranged with a gap between the holding main body arranged along the substrate main body and the holding main body, and holds the substrate main body between the holding main body. It may be provided with a holding piece.

According to such a configuration, the substrate main body can be held by the substrate holding portion with a simple configuration.

In the above configuration, the substrate main body has a positioning hole, and the substrate holding portion is inserted into the holding main body arranged along the substrate main body and the holding main body protruding from the holding main body and inserted into the positioning hole. It may be provided with a positioning protrusion for positioning the substrate main body with respect to the holding main body.

According to such a configuration, the substrate main body can be positioned on the substrate holding portion with a simple configuration.

In the above configuration, the connecting member holding portion includes a base portion arranged along the connecting member and a locking portion connected to the base portion, and the locking portion is projected from the base portion. It may be provided with a bendable portion and a locking claw that protrudes from the bend portion and sandwiches and holds the connecting member between the base portion.

According to such a configuration, the connecting member can be easily assembled to the connecting member holding portion only by pushing the connecting member toward the base portion, so that the assembling workability of the connecting module is improved.

According to the connection module disclosed by the present specification, assembling workability can be improved.

Perspective view of the power storage module of the embodiment Top view of the power storage module of the embodiment Perspective view of the connection module of the embodiment Top view of the connection module of the embodiment Partially enlarged view in frame R1 of FIG. A-A line sectional view of FIG. BB line sectional view of FIG. Cross-sectional view taken along the line CC of FIG. Perspective view of the bus bar of the embodiment Top view of the bus bar of the embodiment Top view of the flexible printed circuit board of the embodiment Perspective view of the resin protector of the embodiment Top view of the resin protector of the embodiment Front view of the resin protector of the embodiment Rear view of the resin protector of the embodiment Partially enlarged view in frame R2 of FIG.

The embodiment will be described with reference to FIGS. 1 to 16. The connection module 1 of the present embodiment constitutes a power storage module M used as a drive source for a vehicle such as an electric vehicle or a hybrid vehicle. As shown in FIG. 1, the connection module 1 is attached to a power storage element group 90G in which a plurality of power storage elements 90 are arranged in a row, and the plurality of power storage elements 90 are connected in series.

[Power storage element 90 and power storage element group 90G]
The power storage element 90 is, for example, a secondary battery. As shown in FIG. 1, each power storage element 90 has a rectangular cuboid shape having a flat outer shape, and has an electrode arrangement surface 90F (upper surface in FIG. 1) perpendicular to a surface facing the adjacent power storage element 90. ing. Electrode terminals 91A and 91B are arranged on the electrode arrangement surface 90F. One of the electrode terminals 91A and 91B is a positive electrode terminal 91A, and the other is a negative electrode terminal 91B. Each of the electrode terminals 91A and 91B has a columnar shape, and a thread is cut on the outer peripheral surface, although not shown in detail.

As shown in FIG. 1, a plurality of power storage elements 90 are arranged in a row to form a power storage element group 90G. In the two energy storage elements 90 adjacent to each other, the plurality of energy storage elements 90 have electrode terminals 91A and 91B having different polarities adjacent to each other (that is, the positive electrode terminal 91A of one energy storage element 90 and the other adjacent terminals 91A). The negative electrode terminals 91B of the power storage element 90 are arranged so as to be adjacent to each other.

In the following description, the arrangement direction of the plurality of power storage elements 90 (lower left-upper right direction in FIG. 1) is the X-axis direction, and the direction along the surface of the power storage element 90 facing the adjacent power storage element 90 (FIG. 1). The lower right-upper left direction) will be described as the Y-axis direction, and the direction perpendicular to the electrode arrangement surface 90F (vertical direction in FIG. 1) will be described as the Z-axis direction.

[Connection module 1]
The connection module 1 is a member of the power storage element group 90G that is assembled to a surface (upper surface in FIG. 1) formed by the electrode arrangement surface 90F of each power storage element 90. As shown in FIG. 3, the connection module 1 is connected to the flexible printed substrate 20 (hereinafter referred to as “FPC20”) and the FPC20, and connects the positive electrode terminal 91A and the negative electrode terminal 91B of the adjacent power storage elements 90. A plurality of bus bars 10 (corresponding to connecting members) and a resin protector 40 (corresponding to holding members) for holding the bus bars 10 and the FPC 20 are provided. Note that FIG. 1 shows only the connection module 1 connected to one of the two rows of the electrode terminals 91A and 91B (lower right row), but the other row is also connected to the connection module 1 in the same manner. 1 is connected. Further, in FIG. 1, in the connection module 1, one bus bar 10 connecting the positive electrode terminal 91A at the right end and the negative electrode terminal 91B adjacent thereto is shown, and the other bus bars 10 are omitted. The same applies to FIG. 2.

(Busbar 10)
Each of the plurality of bus bars 10 is made of metal, and as shown in FIGS. 9 and 10, the electrode connecting portion 11 connecting the positive electrode terminal 91A and the negative electrode terminal 91B of the adjacent power storage elements 90, and the electrode connection thereof. It includes an FPC connection piece 15 connected to the FPC 20 and connected to the unit 11, and a locking wall 16 connected to the FPC connection piece 15.

The electrode connection portion 11 is a rectangular plate-shaped portion as a whole, and has two electrode insertion holes 12 through which the electrode terminals 91A and 91B can be inserted and two engagement recesses for engaging with the resin protector 40. It has 13 and. One electrode insertion hole 12 is arranged at a position close to one short side 11S of the electrode connection portion 11, and one is arranged at a position close to the other short side 11S. One of the two engaging recesses 13 is a recess recessed from one short side 11S of the electrode connecting portion 11, and the other is a recess recessed from the other short side 11S.

The electrode connecting portion 11 has a connecting recess 14 recessed from one of the long sides 11LA and 11LB of the pair of long sides 11LA. The connection recess 14 is a recess defined by a first inner edge 14A parallel to the long side 11LA and a pair of first side edges 14B connecting both ends of the first inner edge 14A and the long side 11LA. .. The FPC connection piece 15 is a rectangular plate-like portion extending from the first inner edge 14A in the same plane as the electrode connection portion 11. The locking wall 16 is a short plate wall-shaped portion extending vertically from the tip of the FPC connection piece 15.

(FPC20)
The FPC 20 is a member for electrically connecting a plurality of bus bars 10 and an ECU (electronic control unit: not shown), and is not shown in detail, but has a plurality of conductive paths formed of copper foil. It is provided with an insulating resin film that covers both sides of the conductive path. As shown in FIG. 11, the FPC 20 includes an FPC main body 21 (corresponding to a substrate main body) having a rectangular band shape as a whole, a plurality of first movable portions 31 connected to the FPC main body 21, and a plurality of first movable portions 31. It is provided with a joining piece 35 which is connected to each of the above and is joined to each of the plurality of bus bars 10.

The FPC main body 21 has a first slit 22, a notch 23, a plurality of positioning holes 24, and two engagement holes 25.

The first slit 22 is located at a substantially central position between the pair of long sides 21LA and 21LB of the FPC main body 21, parallel to the long sides 21LA and 21LB, at both ends of the FPC main body 21 (a pair of short sides 21SA and 21SA), respectively. It is a slit that extends over almost the entire length except for a close part. The notch 23 is a relatively wide gap extending from the long side 21LA of one of the FPC main bodies 21 (lower side in FIG. 11) to the first slit 22, and is one of the FPC main bodies 21 (right side in FIG. 11). ) Is located close to the short side 21SA. The portion of the FPC main body 21 sandwiched between the first slit 22 and the long side 21LA (the portion below the first slit 22 in FIG. 11) is arranged on the short side 21SB side by the notch portion 23. It is divided into a long first dividing portion 26 and a short second dividing portion 27 arranged on the short side 21SA side.

The plurality of positioning holes 24 are arranged at a position close to one short side 21SA, two at a position close to the other short side 21SB, and one at a substantially central position of the first dividing portion 26. One of the two engaging holes 25 is arranged at a position close to the notch 23 in the first dividing portion 26, and the other is arranged at a position close to the notch 23 in the second dividing portion 27.

The first movable portion 31 is composed of a linear spring-shaped portion (corresponding to the first spring portion) connected to the FPC main body 21, extends from the long side 21LA of the FPC main body 21, and is curved in a U shape. A straight portion 32 (corresponding to a curved portion), a straight portion 33 extending from the extending end of the first curved portion 32 and extending along the long side 21LA, and a straight portion 33 continuing from the extending end of the straight portion 33, and the first curved portion 32. Is provided with a second curved portion 34 (corresponding to the curved portion) that curves in a U shape in the opposite direction, and has a substantially S shape as a whole. The plurality of first movable portions 31 are arranged side by side in a row along the long side 21LA, one of which is continuous from the second dividing portion 27, and the rest from the first dividing portion 26. It is in a row.

The joint piece 35 is a rectangular plate-shaped portion continuous from the extending end of the second curved portion 34. A part of the conductive path is exposed as a joining land (not shown) on one surface of the joining piece 35, and the FPC connecting piece 15 is connected to this by soldering.

(Resin protector 40)
The resin protector 40 is made of synthetic resin and includes an FPC holding portion 41 (corresponding to a substrate holding portion) for holding the FPC main body 21, and a plurality of bus bar holding portions 61 and 71 for holding the bus bar 10.

As shown in FIG. 12, the FPC holding portion 41 includes a holding plate portion 42 (corresponding to the holding body), side ribs 43 and center ribs 44A and 44B extending from the holding plate portion 42, a plurality of holding pieces 45, and a plurality of holding pieces 45. It includes a positioning protrusion 46 and two FPC locking pieces 47.

The holding plate portion 42 has a rectangular plate shape having a size substantially equal to that of the FPC main body 21 as a whole. One surface (upper surface of FIG. 12) of the holding plate portion 42 is a mounting surface 42F on which the FPC main body 21 is mounted, and the side ribs 43, center ribs 44A, and 44B and holding pieces are placed on the mounting surface 42F. 45, a positioning protrusion 46 and an FPC locking piece 47 are arranged.

The side rib 43 is a streak-shaped portion protruding from the long side 42LA of one of the pair of long sides 42LA and 42LB (upper part of FIG. 12) of the holding plate portion 42, and is arranged over almost the entire length of the long side 42LA. There is. The center ribs 44A and 44B are streak-shaped portions extending in parallel with the long sides 42LA and 42LB at substantially the center position between the pair of long sides 42LA and 42LB, and the pair of short sides 42SA and 42SB of the holding plate portion 42. One of the long sides (left side of FIG. 12) is located close to the short side 42SA, and the other short side is located close to the other short side 42SB.

Each of the plurality of holding pieces 45 is a plate piece-shaped portion extending in parallel with the holding plate portion 42 from the side rib 43, and can be held by sandwiching the FPC main body 21 with the holding plate portion 42. .. Each of the plurality of positioning protrusions 46 is a circular protrusion extending from the holding plate portion 42, and is arranged at a position corresponding to each of the plurality of positioning holes 24 of the FPC main body 21. As shown in FIG. 8, each of the two FPC locking pieces 47 includes a locking piece main body 47A extending from the holding plate portion 42 and a locking projection 47B protruding from the tip of the locking piece main body 47A. , Are arranged at positions corresponding to each of the two engagement holes 25 of the FPC main body 21.

The holding plate portion 42 has a plurality of spring recesses 48 that are recessed inward from the other long side 42LB (corresponding to one edge). As shown in FIG. 16, the spring recess 48 is formed by a second inner edge 48A parallel to the long side 42LB and a pair of second side edges 48B connecting both ends of the second inner edge 48A and the long side 42LB. A recess as defined.

As shown in FIG. 12, of the plurality of bus bar holding portions 61, 71, one closest to one short side 42SA of the holding plate portion 42 is the fixed bus bar holding portion 71, and the other is the second movable portion. The movable bus bar holding portion 61 (corresponding to the connecting member holding portion) connected to the holding plate portion 42 via the 51.

As shown in FIGS. 15 and 16, the second movable portion 51 has a plate shape bent in a bellows shape as a whole, and can be expanded and contracted in a direction along the long side 42LB of the holding plate portion 42. .. More specifically, the second movable portion 51 has a plate-shaped spring connecting piece 52 (corresponding to the spring connecting portion) extending from the second inner edge 48A on the same plane as the holding plate portion 42, and the spring connecting portion. A pair of spring plate portions 53 (corresponding to the second spring portion) extending from the piece 52 along the second inner edge 48A while bending in opposite directions are provided. Each of the pair of spring plate portions 53 extends vertically from the extending end of the spring connecting piece 52 so as to be away from the holding plate portion 42, then is folded back and extends toward the holding plate portion 42, and is further folded back. It has an S-shaped leaf spring shape that extends away from the holding plate portion 42.

As shown in FIG. 16, the movable bus bar holding portion 61 includes a back plate portion 62 connected to the second movable portion 51, a bottom plate portion 63 (corresponding to the base) connected to the back plate portion 62, and an extension piece extending from the bottom plate portion 63. 65, a first bus bar locking piece 66 (corresponding to a locking portion), two second bus bar locking pieces 67 (corresponding to a locking portion), and a pair of abutting plates 68.

As shown in FIG. 16, the back plate portion 62 is a plate-shaped portion arranged in a posture perpendicular to the holding plate portion 42, and is connected to the respective tip portions of the pair of spring plate portions 53. There is.

As shown in FIG. 16, the bottom plate portion 63 is a plate-shaped portion extending vertically from the back plate portion 62 in the direction opposite to the holding plate portion 42, and has two second slits 64. As shown in FIGS. 13 and 16, each of the two second slits 64 extends from the extending end of the bottom plate portion 63 toward the back plate portion 62, and the bottom plate portion is provided by these second slits 64. 63 is divided into end plate portions 63A at both ends and a middle plate portion 63B at the center. The extension piece 65 is a plate-like portion extending from the extending end of the bottom plate portion 63 on the same surface as the bottom plate portion 63.

As shown in FIGS. 6 and 16, the first bus bar locking piece 66 extends from the middle plate portion 63B and is arranged with a gap with respect to the back plate portion 62 (corresponding to the bending portion). ), And a first locking claw 66B (corresponding to the locking claw) protruding in the direction opposite to the back plate portion 62 from the extending end of the first bending piece 66A. The first bending piece 66A is slightly inclined so as to be separated from the back plate portion 62 as the distance from the middle plate portion 63B is increased.

As shown in FIG. 7, each of the two second bus bar locking pieces 67 has a second bending piece 67A (corresponding to the bending part) extending vertically from the extending end of the two end plate portions 63A and a second bending portion. It is provided with a second locking claw 67B (corresponding to a locking claw) protruding from the tip of the piece 67A toward the back plate portion 62.

As shown in FIG. 16, each of the two abutting plates 68 is a plate-shaped portion protruding from the middle plate portion 63B along the slit edge of each of the two second slits 64, and is a back plate portion. It is arranged adjacent to 62.

Each movable bus bar holding portion 61 is allowed to be displaced with respect to the holding plate portion 42 to some extent by the second movable portion 51. Specifically, by expanding and contracting the two spring plate portions 53 of the second movable portion 51, the holding plate portion 42 can move in the direction along the long side 42LB (X-axis direction).

As shown in FIG. 12, the fixed bus bar holding portion 71 does not have the second movable portion 51, and the movable bus bar is a movable bus bar except that the back plate portion 72 extends from the long side 42LB of the holding plate portion 42. It has the same configuration as the holding portion 61. In the fixed bus bar holding portion 71, the same parts as those of the movable bus bar holding portion 61 are designated by the same reference numerals, and the description thereof will be omitted.

As shown in FIGS. 12 and 16, the fixed bus bar holding portion 71, the movable bus bar holding portion 61 adjacent to the fixed bus bar holding portion 71, and the adjacent movable bus bar holding portions 61 are connected to each other by a U-shaped leaf spring-shaped connecting portion 81. It is connected. As a result, the fixed bus bar holding portion 71, the movable bus bar holding portion 61 adjacent to the fixed bus bar holding portion 71, and the adjacent movable bus bar holding portions 61 are aligned along the long side 42LB of the holding plate portion 42 (X-axis direction). It is possible to stably hold a plurality of bus bars 10 assembled to the fixed bus bar holding portion 71 and the movable bus bar holding portion 61 by connecting them without hindering the displacement in the direction.

[Assembly of connection module 1]
An example of the procedure for assembling the connection module 1 having the above configuration will be described below.

First, a plurality of bus bars 10 are connected to the FPC 20. The FPC connection piece 15 of each bus bar 10 is superposed on each joint piece 35 of the FPC 20 and joined by reflow soldering. In the state of being connected to the FPC 20, as shown in FIGS. 3 and 5, each bus bar 10 is connected to the FPC main body 21 via the first movable portion 31, and the first movable portion 31 is connected to the FPC main body 21. By deforming, each bus bar 10 has a direction along the long side 21LA of the FPC main body 21 (X-axis direction), a direction close to / separated from the FPC main body 21 (Y-axis direction), and a thickness of the FPC main body 21. It can be freely displaced to some extent in any direction (Z-axis direction).

Next, the bonded body of the FPC 20 and the plurality of bus bars 10 is assembled to the resin protector 40.

First, the FPC main body 21 is assembled to the FPC holding portion 41. As shown in FIG. 3, the FPC main body 21 is placed on the holding plate portion 42 so as to be inserted into the gap between the holding plate portion 42 and the holding piece 45, and the long side 21LB is set along the side rib 43. The FPC main body 21 is positioned on the holding plate portion 42 by inserting each of the plurality of positioning protrusions 46 into each of the plurality of positioning holes 24 and inserting the two center ribs 44A and 44B into the first slit 22. Slit. Further, the FPC main body 21 is pressed by the pressing piece 45 so as not to come off from the holding plate portion 42. As shown in FIGS. 3 and 8, the locking piece main body 47A of each FPC locking piece 47 is inserted into each engaging hole 25, and the locking projection 47B engages with the FPC main body 21, so that each divided portion is formed. The ends of 26 and 27 are pressed so as not to be turned up from the holding plate portion 42.

Next, each bus bar 10 is assembled to each bus bar holding portion 61, 71. Each second bus bar locking piece 67 is inserted into each engaging recess 13, and the electrode connecting portion 11 is pushed toward the bottom plate portion 63 while bending the first bus bar locking piece 66 by the locking wall 16. When the electrode connecting portion 11 abuts on the bottom plate portion 63, as shown in FIG. 6, the first bus bar locking piece 66 elastically returns, and the locking wall 16 becomes the middle plate portion 63B and the first locking claw 66B. It is sandwiched between. Further, as shown in FIGS. 5 and 7, a portion of the electrode connecting portion 11 adjacent to the engaging recess 13 enters between the bottom plate portion 63 and the second locking claw 67B. As a result, each bus bar 10 is fixed to each bus bar holding portion 61, 71. At this time, since the bus bar 10 is allowed to be freely displaced with respect to the FPC main body 21 by deforming the first movable portion 31, the bus bar 10 can be easily assembled to the bus bar holding portions 61 and 71. It can be carried out. Further, since the bus bar 10 can be easily assembled to the bus bar holding portions 61 and 71 only by pushing the bus bar 10 toward the bottom plate portion 63, the assembly workability of the connection module 1 is improved.

In a state where the bus bar 10 is assembled to the bus bar holding portions 61 and 71, as shown in FIG. 3, the first curved portion 32 is arranged in the same plane as the FPC main body 21, and the straight portion 33 is the first. The farther away from the curved portion 32, the more it is inclined so as to be away from the FPC main body 21. The second curved portion 34, the joining piece 35, and the bus bar 10 are arranged parallel to the FPC main body 21 and separated from the FPC main body 21. The straight line portion 33 is passed through a gap between the first bus bar locking piece 66 and the back plate portion 62.

In the completed connection module 1, the FPC main body 21 is held in the positioned state with respect to the FPC holding unit 41. Further, each bus bar 10 is held in a positioned state by each movable bus bar holding portion 61. The bus bar 10 is displaceably connected to the FPC main body 21 by the first movable portion 31, and the movable bus bar holding portion 61 is displaceably connected to the FPC holding portion 41 by the second movable portion 51. As a result, the movable bus bar holding portion 61 and the bus bar 10 are assembled to each other, and the long side 42LB of the holding plate portion 42 and the long side 21LA of the FPC main body 21 are attached to the FPC holding portion 41 and the FPC main body 21. Displacement in the direction along (X-axis direction) is allowed.

[Assembly of connection module 1 to storage element group 90G]
An example of the procedure for assembling the connection module 1 having the above configuration to the power storage element group 90G will be described below.

As shown in FIGS. 1 and 2, the connection module 1 is arranged at a predetermined position on the power storage element group 90G, and the electrode terminals 91A and 91B are inserted into the electrode insertion holes 12 of each bus bar 10. After that, the electrode terminals 91A and 91B and the bus bar 10 are connected by screwing nuts (not shown) to the electrode terminals 91A and 91B.

Here, the power storage element group 90G configured by arranging a large number of power storage elements 90 has a dimensional tolerance due to a manufacturing dimensional error of each power storage element 90, an assembly error of a plurality of power storage elements 90, and the like. As a result, the electrode terminals 91A and 91B may be displaced in the direction (X-axis direction) along the arrangement direction of the power storage elements 90. In the present embodiment, as described above, the movable bus bar holding portion 61 and the bus bar 10 are allowed to be displaced with respect to the FPC holding portion 41 and the FPC main body 21, so that the electrodes are caused by the dimensional tolerance of the power storage element group 90G. Each bus bar 10 can be displaced and assembled to the electrode terminals 91A and 91B in response to the positional deviation of the terminals 91A and 91B.

For example, when the distance between the electrode terminals 91A and 91B is smaller than the design dimension, the second movable portion 51 and the connecting portion 81 are deformed so that each movable bus bar holding portion 61 is referred to the fixed bus bar holding portion 71. As a result, the bus is displaced in a direction close to the fixed bus bar holding portion 71 (direction along the long side 42LB of the holding plate portion 42: a direction from the upper right to the lower left in FIG. 1). In other words, with respect to the fixed bus bar holding portion 71 located at one end of the resin protector 50, the movable bus bar holding portion 61 located next to the fixed bus bar holding portion 71 and the adjacent movable bus bar holding portions 61 are closely spaced from each other. The movable bus bar holding portion 61 is displaced so as to be. As a result, the other bus bars 10 are displaced so that the distance between the adjacent bus bars 10 becomes smaller with respect to one bus bar 10 held by the fixed bus bar holding portion 71, and the positions of the electrode terminals 91A and 91B can be displaced. can do.

When the distance between the electrode terminals 91A and 91B is larger than the design dimension, the second movable portion 51 and the connecting portion 81 are deformed so that each movable bus bar holding portion 61 is referred to the fixed bus bar holding portion 71. As a result, the bus bar is displaced in a direction away from the holding portion 71 (direction along the long side 42LB of the holding plate portion 42: a direction from the lower left to the upper right in FIG. 1). In other words, with respect to the fixed bus bar holding portion 71 located at one end of the resin protector 50, the movable bus bar holding portion 61 located next to the fixed bus bar holding portion 71 and the adjacent movable bus bar holding portions 61 are widely spaced from each other. The movable bus bar holding portion 61 is displaced so as to be. As a result, the other bus bars 10 are displaced so that the distance between the adjacent bus bars 10 becomes large with respect to one bus bar 10 held by the fixed bus bar holding portion 71, and the positions of the electrode terminals 91A and 91B can be displaced. can do.

In this way, it is possible to prevent the connection module 1 from being difficult to assemble to the power storage element group 90G due to the dimensional tolerance of the power storage element group 90G, and to improve the assembly workability.

Further, by assembling the FPC 20 and the plurality of bus bars 10 to the resin protector 40, the shape of the flexible FPC 20 is kept constant, and the FPC 20 and the plurality of bus bars 10 are collectively placed at a predetermined position on the power storage element group 90G. Since it can be set, assembly workability can be improved.

[summary]
As described above, according to the present embodiment, the connection module 1 is a module attached to a power storage element group 90G composed of a plurality of power storage elements 90 including electrode terminals 91A and 91B to connect the plurality of power storage elements 90. The FPC 20 is provided with a plurality of bus bars 10 connected to the FPC 20 to connect the electrode terminals 91A and 91B of the adjacent power storage elements 90, and a resin protector 40 for holding the bus bar 10 and the FPC 20. The FPC 20 includes an FPC main body 21, a first movable portion 31 that connects the FPC main body 21 and the bus bar 10, a resin protector 40, an FPC holding portion 41 to which the FPC main body 21 is fixed, and a bus bar 10. It includes a movable bus bar holding portion 61 to be fixed, and a plurality of second movable portions 51 connecting the FPC holding portion 41 and the movable bus bar holding portion 61. The first movable portion 31 and the second movable portion 51 connect the bus bar 10 and the movable bus bar holding portion 61 to the FPC main body 21 and the FPC holding portion 41 while allowing displacement.

According to the above configuration, since the bus bar 10 and the movable bus bar holding portion 61 are allowed to be displaced with respect to the FPC main body 21 and the FPC holding portion 41 in a state of being assembled with each other, the dimensional tolerance of the power storage element group 90G is allowed. It is possible to avoid difficulty in assembling the connection module 1 to the power storage element group 90G due to the displacement of the electrode terminals 91A and 91B due to the above, and improve the assembling workability. Further, by holding the FPC 20 and the plurality of bus bars 10 in the resin protector 40, the shape of the flexible FPC 20 is kept constant, and the FPC 20 and the plurality of bus bars 10 are collectively placed in a predetermined position of the power storage element group 90G. Since it can be set, assembly workability can be improved.

Further, the first movable portion 31 extends from the FPC main body 21 and is composed of a wire spring having a first curved portion 32 and a second curved portion 34.

According to such a configuration, the bus bar 10 can be connected to the FPC main body 21 while allowing displacement with a simple configuration. Further, by forming the first movable portion 31 with a wire spring, the bus bar 10 is located in any of the directions of proximity to and away from the FPC main body 21, the thickness direction of the FPC main body 21, and the direction along the FPC main body 21. However, since the bus bar 10 can be freely displaced to some extent, the assembly work when assembling to the resin protector 40 after connecting the bus bar 10 to the FPC 20 can be easily performed.

Further, a plurality of second movable portions 51 are arranged side by side along the long side 42LB of the FPC holding portion 41, and each of the plurality of second movable portions 51 can be expanded and contracted in the direction along the long side 42LB. A spring plate portion 53 is provided.

According to such a configuration, the second movable portion 51 allows the movable bus bar holding portion 61 to be displaced in the direction along the long side 42LB of the FPC holding portion 41. Therefore, by assembling the connection module 1 to the power storage element group 90G so that the long side 42LB of the FPC holding unit 41 extends along the arrangement direction of the plurality of power storage elements 90, the movable bus bar holding unit 61 and the movable bus bar holding portion 61 are held. Displacement of the bus bar 10 held by the unit 61 in the direction along the arrangement direction of the power storage element group 90G is allowed. As a result, it is possible to prevent the connection module 1 from being difficult to assemble to the power storage element group 90G due to the positional deviation of the electrode terminals 91A and 91B due to the dimensional tolerance of the power storage element group 90G, and to improve the assembly workability. can.

Further, the resin protector 50 may include a connecting portion 81 that connects the adjacent movable bus bar holding portions 61 while allowing displacement of the holding plate portion 42 in the FPC holding portion 41 in the direction along the long side 42LB. do not have.

According to such a configuration, the movable bus bar holding portions 61 are connected to each other without hindering the displacement of the movable bus bar holding portion 61 in the direction along the arrangement direction of the power storage element group 90G, and the plurality of bus bars 10 are stabilized. Can be held.

Further, the FPC holding portion 41 is arranged with a gap between the holding plate portion 42 arranged along the FPC main body 21 and the holding plate portion 42, and holds the FPC main body 21 between the holding plate portion 42. It is provided with a holding piece 45 to be used.

According to such a configuration, the FPC main body 21 can be held by the FPC holding unit 41 with a simple configuration.

Further, the FPC main body 21 has a positioning hole 24, and the FPC holding portion 41 protrudes from the holding plate portion 42 arranged along the FPC main body 21 and the holding plate portion 42 and is inserted into the positioning hole 24. It is provided with a positioning protrusion 46 for positioning the FPC main body 21 with respect to the holding plate portion 42.

According to such a configuration, the FPC main body 21 can be positioned on the FPC holding unit 41 with a simple configuration.

Further, the movable bus bar holding portion 61 includes a bottom plate portion 63 arranged along the bus bar 10, a first bus bar locking piece 66 and a second bus bar locking piece 67 connected to the bottom plate portion 63. The first bus bar locking piece 66 projects from the bottom plate portion 63 and projects from the first flexible piece 66A that can bend, and projects from the first flexible piece 66A to sandwich and hold the bus bar 10 between the bottom plate portion 63. It is provided with a first locking claw 66B. Similarly, the second bus bar locking piece 67 projects from the bottom plate portion 63 and sandwiches the bus bar 10 between the flexible second flexible piece 67A and the bottom plate portion 63 protruding from the second flexible piece 67A. It is provided with a second locking claw 67B for holding the bus.

According to such a configuration, the bus bar 10 can be easily assembled to the movable bus bar holding portion 61 simply by pushing the bus bar 10 toward the bottom plate portion 63, so that the assembling workability of the connection module 1 is improved.

<Other embodiments>
The techniques disclosed herein are not limited to the embodiments described above and in the drawings, and include, for example, various embodiments such as:

(1) In the above embodiment, the first movable portion 31 includes the first curved portion 32 and the second curved portion 34, but the number of curved portions may be one or three or more.

(2) In the above embodiment, the second movable portion 51 includes a pair of spring plate portions 53 that bend in a bellows shape, but the shape of the second spring portion is not limited to the above embodiment and is one of the substrate holding portions. It suffices to have a spring shape that can expand and contract in the direction along the edge.

(3) In the above embodiment, the two spring plate portions 53 of the second movable portion 51 have a symmetrical shape with the spring connecting piece 52 interposed therebetween, but the pair of second spring portions have an asymmetrical shape with each other. You may have.

1 ... Connection module 10 ... Bus bar (connecting member)
20 ... Flexible printed circuit board 21 ... FPC body (board body)
24 ... Positioning hole 31 ... First movable part (first spring part)
32 ... First curved portion (curved portion)
34 ... Second curved portion (curved portion)
40 ... Resin protector (holding member)
41 ... FPC holding part (board holding part)
42 ... Holding plate (holding body)
45 ... Holding piece 46 ... Positioning protrusion 51 ... Second movable part 53 ... Spring plate part (second spring part)
61 ... Movable bus bar holding part (connecting member holding part)
63 ... Bottom plate (base)
66 ... First bus bar locking piece (locking portion)
66A ... 1st flexible piece (flexible part)
66B ... 1st locking claw (locking claw)
67 ... Second bus bar locking piece (locking portion)
67A ... 2nd flexible piece (flexible part)
67B ... Second locking claw (locking claw)
81 ... Connecting part 90 ... Power storage element 90G ... Power storage element group 91A, 91B ... Electrode terminal

Claims (7)

A connection module attached to a group of power storage elements composed of a plurality of power storage elements provided with electrode terminals to connect the plurality of power storage elements.
Flexible printed circuit board and
A plurality of connecting members connected to the flexible printed substrate and connecting the electrode terminals of the adjacent storage elements to each other.
A holding member for holding the plurality of connecting members and the flexible printed circuit board is provided.
The flexible printed circuit board includes a board body and a first movable portion that connects the board body and the connecting member.
The holding member has a substrate holding portion to which the substrate main body is fixed, a connecting member holding portion to which the connecting member is fixed, and a second movable portion connecting the substrate holding portion and the connecting member holding portion. I have
A connection module in which the first movable portion and the second movable portion connect the connecting member and the connecting member holding portion while allowing displacement with respect to the substrate main body and the substrate holding portion. .. The connection module according to claim 1, wherein the first movable portion extends from the substrate main body and includes a wire spring-shaped first spring portion having at least one curved portion. A plurality of the second movable portions are arranged side by side along one edge of the substrate holding portion.
The connection module according to claim 1 or 2, wherein each of the plurality of second movable portions includes a second spring portion that can expand and contract in a direction along the one edge. The connection module according to claim 3, wherein the holding member comprises a connecting portion that connects adjacent connecting member holding portions while allowing displacement in a direction along the one edge. The substrate holding portion includes a holding body arranged along the board body and a holding piece arranged with a gap from the holding body and holding the board body between the holding body. The connection module according to any one of claims 1 to 4. The board body has a positioning hole, and the substrate body has a positioning hole.
The board holding portion includes a holding body arranged along the board body and a positioning projection for positioning the board body with respect to the holding body by protruding from the holding body and being inserted into the positioning hole. The connection module according to any one of claims 1 to 5. The connecting member holding portion
It includes a base portion arranged along the connection member and a locking portion connected to the base portion.
A claim that the locking portion comprises a flexible portion that protrudes from the base and is flexible, and a locking claw that projects from the flexible portion and sandwiches and holds the connecting member between the base. The connection module according to any one of 1 to 6.

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