JP6814185B2 - Battery module - Google Patents

Description

The present invention, by laminating a plurality of cells comprising positive and negative electrodes, relates to a battery module having a configured cell collection connect each electrode of the plurality of cells.

For example, Patent Document 1 discloses connecting two electrodes of adjacent cells of a battery module by welding or bolting.

Japanese Unexamined Patent Publication No. 2015-207437

However, when a cell malfunctions or maintenance of the battery module is required, the cell cannot be easily replaced or maintained. As a result, it is necessary to replace the entire battery module, not the cell alone. As a result, the man-hours and costs required for replacement increase.

The present invention has been made in consideration of such a problem, and provides a battery module capable of easily performing cell replacement and maintenance, and reducing man-hours and costs required for replacement. The purpose is .

State like the present invention, by laminating a plurality of cells comprising positive and negative electrodes, a battery module having a configured cell collection connect each electrode of the plurality of cells, adjacent to the stacking direction 2 A plurality of the cells are stacked in the stacking direction so that the positive and negative electrodes are staggered between the cells, and the cell assembly includes a plurality of spacers and is of the two adjacent cells. By sandwiching the positive electrode of one cell and the negative electrode of the other cell between the plurality of spacers and connecting them, the plurality of the cells are connected in series.

According to state-like of the present invention, since a simple connection structure of connecting sandwiches the positive and negative electrodes of adjacent two cells in a plurality of spacers, it is possible to perform the replacement or maintenance of the cell easy, The man-hours and costs required for replacement can be reduced.

It is a left side view of the electric vehicle to which the battery module which concerns on this embodiment and the storage structure thereof are applied. It is a perspective view of a battery case. It is an exploded perspective view of a battery case. It is a perspective view of a battery module. It is a perspective view of another configuration example of a battery module. It is a perspective view of another configuration example of a battery module. It is a perspective view of another configuration example of a battery module. It is a conceptual diagram which schematically illustrated the connection relationship between cells of a battery module. 9A is a perspective view of the cell, and FIG. 9B is a perspective view of the cell after bending. 10A and 10B are perspective views of the cell after bending. 11A and 11B are perspective views of the cell after bending. FIG. 12A is an exploded perspective view of the first spacer, and FIG. 12B is a perspective view of the first spacer. FIG. 13A is an exploded perspective view of the second spacer, and FIG. 13B is a perspective view of the second spacer. FIG. 14A is an exploded perspective view of the third spacer, and FIG. 14B is a perspective view of the third spacer. It is an exploded perspective view of the 4th spacer. 16A and 16B are perspective views of the fourth spacer. It is a perspective view which illustrated the state of stacking a plurality of cells. It is explanatory drawing which illustrated the connection state of the electrode between adjacent cells. It is a perspective view which illustrated the state which attached the spacer and the output terminal to one end side of a cell assembly. It is a perspective view which illustrated the state which attached the spacer and the output terminal to the other end side of a cell assembly. It is explanatory drawing which illustrated the connection state of the electrode and the output terminal in FIG. It is a perspective view which illustrated the state which fastened a plurality of spacers with bolts and nuts. It is a perspective view which illustrated the state which a plurality of spacers were fastened in the stacking direction. It is a perspective view which illustrated the state which attached the BMS substrate to a cell aggregate. It is a perspective view which illustrated the state which stores the cell aggregate in a case. It is a perspective view which illustrated the state which accommodates a plurality of battery modules in a lower case. It is a perspective view which illustrated the state which accommodates a plurality of battery modules in an intermediate case. It is a perspective view which illustrated the state which accommodates a plurality of battery modules in an intermediate case. It is a perspective view which illustrated the state which accommodates a plurality of battery modules in an upper case.

Hereinafter, with the battery module according to the present invention illustrate preferred embodiments will be described with reference to the accompanying drawings.

[1. Outline configuration of electric vehicle 14]
FIG. 1 is a left side view of the battery module 10 according to the present embodiment and the electric vehicle 14 to which the storage structure thereof is applied. In the following description, the front-back, left-right, and up-down directions as viewed from the driver seated on the seat 16 of the electric vehicle 14 will be described.

The electric vehicle 14 is a saddle-mounted electric motorcycle, and includes a body frame 18. A head pipe 20 is provided at the front end of the vehicle body frame 18. The head pipe 20 supports the handle 22 so as to be steerable. The driver steers the front wheels 26 via the front fork 24 by operating the steering wheel 22.

The battery 28 is housed in a battery case 30 supported by a vehicle body frame 18. As will be described later, the storage structure of the battery module 10 according to the present embodiment is applied to the battery case 30. A seat 16 is supported behind the vehicle body frame 18. A rotary electric machine 31 is supported by the vehicle body frame 18 at the rear of the vehicle body frame 18 and below the seat 16. Further, an inverter 32 is supported below the vehicle body frame 18. Further, a swing arm 34 is supported on the rear portion of the vehicle body frame 18 so as to be swingable up and down around the pivot shaft 36. A rear wheel 38 is supported at the rear end of the swing arm 34.

The rotary electric machine 31 is a drive electric motor that is driven by the converted AC power when the inverter 32 converts the DC power supplied from the battery 28 into AC power. The electric vehicle 14 travels by transmitting the output of the rotary electric machine 31 to the rear wheels 38. On the other hand, at the time of regeneration of the rotary electric machine 31, the AC power generated by the rotary electric machine 31 is converted into DC power by the inverter 32 and charged to the battery 28.

The electric vehicle 14 is covered with a wind screen 52 and a cover member 54 such as a cowl.

[2. Configuration of battery 28 and battery case 30]
As shown in FIGS. 1 to 3, a plurality of battery modules 10 are arranged in the front-rear direction or the left-right direction (horizontal direction), and are housed in a multi-tiered state in the vertical direction. There is. The battery 28 is configured by electrically connecting these battery modules 10 in series.

As shown in FIGS. 4 to 9B, the battery module 10 is in a state where a plurality of thin cells 62 having two positive and negative electrodes 60 (positive electrode 60p, negative electrode 60m) are laminated in one direction (stacking direction). , Has a cell assembly 64 in which each electrode 60 of a plurality of cells 62 is connected. The cell 62 is a laminated battery cell, and has a shape in which positive and negative electrodes 60 extend in one direction from a thin cell body 66. As such a laminated type battery cell, a battery cell of a lithium ion battery is suitable. Further, the positive and negative electrodes 60 are made of a flexible conductive member, for example, a flexible metal electrode (electrode tab) that can be bent.

In the present embodiment, any kind of battery cell (for example, the above-mentioned lithium ion battery or lead battery cell) can be used as long as the cells 62 can be stacked in one direction to form the battery module 10. May be good. Further, in the present embodiment, for simplification of the illustration, only the cells 62 at both ends in the stacking direction may be shown for one battery module 10, and the illustration of the plurality of cells 62 in the middle may be omitted.

Here, when a plurality of cells 62 are stacked with the thickness direction of the cell body 66 as the stacking direction, positive and negative electrodes 60 are provided between the two cells 62 adjacent to each other in the stacking direction, as conceptually shown in FIG. A plurality of cells 62 are laminated in the stacking direction so as to be staggered (alternate). In the following description, among the positive and negative electrodes 60 of the plurality of cells 62, the positive electrode 60 may be referred to as a positive electrode 60p, and the negative electrode 60 may be referred to as a negative electrode 60m. Further, in the following description, regarding the two electrodes 60 (positive electrode 60p and negative electrode 60m) provided in one cell 62 and the two cells 62 adjacent to each other in the stacking direction, the positive electrode 60p of one cell 62 and the other electrode 60p The negative electrode 60m of the cell 62 may be referred to as a “positive / negative electrode 60”.

In the cell assembly 64, of the two cells 62 adjacent to each other in the stacking direction, the positive electrode 60p of one cell 62 and the negative electrode 60m of the other cell 62 are sandwiched between the two spacers 68 in the stacking direction. The positive electrode 60p and the negative electrode 60m are connected. As a result, in the cell assembly 64, the plurality of cells 62 are connected in series by the plurality of spacers 68. The plurality of spacers 68 are fastened in the stacking direction by screwing bolts and nuts (bolts 122 and nuts 124 described later) that are inserted in the stacking direction. The specific configuration of the spacer 68 will be described later.

The plurality of cell bodies 66 are housed in a metal case 70 (storage body) so that the positive and negative electrodes 60 are exposed to the outside. Further, a positive electrode 60p of the cell 62 arranged at one end of the cell assembly 64 in the stacking direction is provided with a positive electrode output terminal 72p. Further, a negative electrode 60m of the cell 62 arranged at the other end of the cell assembly 64 in the stacking direction is provided with a negative electrode output terminal 72m. As shown in FIGS. 4 to 7, various shapes can be adopted for the output terminals 72m and 72p. The output terminals 72m and 72p will also be described later.

The connection point between the positive electrode 60p of one cell 62 and the negative electrode 60m of the other cell 62 and the positive electrode 60p of the cell 62 at one end in the stacking direction of the cell assembly 64 (positive electrode output terminal 72p). And the negative electrode 60m (negative output terminal 72m) of the cell 62 at the other end of the stacking direction of the cell assembly 64, the cell voltage detecting substrate 74 for detecting the voltage of a plurality of cells 62 ( Hereinafter, it is also referred to as a BMS substrate 74). The BMS substrate 74 is a part of a battery management system (BMS) that monitors the battery module 10, and is arranged on the upper portion of the battery module 10 so as to cover the plurality of spacers 68 from above. It should be noted that FIGS. 4 to 7 show a case where the two BMS boards 74 are arranged in the battery module 10.

The plurality of battery modules 10 configured in this way are housed in the battery case 30. As shown in FIGS. 1 to 3, the battery case 30 is a case formed in a saddle shape, a trapezoidal shape, or a convex shape according to the shape of the electric vehicle 14. The battery case 30 is composed of a lower case 78, which is the bottom of the battery case 30, an intermediate case 80 arranged above the lower case 78, and an upper case 82 arranged above the intermediate case 80. To.

The lower case 78 is a case in which the upper flange 78c is provided on the wall portion 78b that stands above the bottom plate portion 78a. In the lower case 78, inside the wall portion 78b, a plurality of battery modules 10 are arranged in the front-rear direction in a state in which a plurality of battery modules 10 are laid sideways in the left-right direction (a state in which the BMS substrate 74 faces the left or right direction). There is.

The intermediate case 80 is a case in which the frame body 80b is erected above the rectangular bottom plate portion 80a. In the intermediate case 80, a plurality of battery modules 10 are arranged in the horizontal direction inside the frame body 80b in a state in which a plurality of battery modules 10 are erected in the vertical direction (a state in which the BMS substrate 74 faces upward).

The upper case 82 is a case in which the frame body 82b is erected above the rectangular bottom plate portion 82a. In the upper case 82, a plurality of battery modules 10 are arranged in the horizontal direction in a state of being erected in the vertical direction inside the frame body 82b.

In this case, the plurality of battery modules 10 are battery cases so that the number of battery modules 10 housed in the lower intermediate case 80 is larger than the number of battery modules 10 housed in the upper case 82 on the upper stage side. Arranged within 30.

As shown in FIG. 3, the lower case 78, the intermediate case 80, and the upper case 82 are integrally configured in the vertical direction by screwing a bolt 84 to be inserted in the vertical direction into the screw hole 86.

[3. How to store the battery 28 (battery module 10)]
<Preparation of 3.1 cell 62>
Next, a method of storing the battery module 10 according to the present embodiment in the battery case 30 will be described with reference to FIGS. 9A to 29. In this description, if necessary, the description will be made with reference to FIGS. 1 to 8.

First, a plurality of cells 62 constituting the battery module 10 are prepared. As shown in FIG. 9A, the positive and negative electrodes 60 (positive electrode 60p, negative electrode 60m) extend in one direction from the cell body 66. Therefore, using a known bending method, the positive and negative electrodes 60 are bent. 9B to 11B show the bent cell 62.

In FIG. 9B, the positive electrode 60p and the negative electrode 60m are bent into a substantially U-shape.

In FIG. 10A, the positive electrode 60p and the negative electrode 60m of the cell 62 are bent into a substantially L shape. In this case, the positive electrode 60p and the negative electrode 60m are each bent into a substantially L shape with the tip portions folded back.

In FIG. 10B, the positive electrode 60p extends in one direction with the tip portion folded back. On the other hand, the negative electrode 60 m is bent into a substantially L shape with the tip portion folded back.

In FIG. 11A, the positive electrode 60p and the negative electrode 60m are each bent into a substantially L shape with the tip portions folded back.

In FIG. 11B, the positive electrode 60p is bent into a substantially L shape with the tip portion folded back. On the other hand, the negative electrode 60 m extends in one direction with the tip portion folded back.

The shapes of the positive electrode 60p and the negative electrode 60m are not limited to the examples of FIGS. 9B to 11B, and of course, they may be appropriately changed according to the configuration of the spacer 68 described later.

<3.2 Stacking of cells 62>
After the positive electrode 60p and the negative electrode 60m are bent in this way, the plurality of cells 62 are laminated in the stacking direction. In this case, the thickness direction of the cell body 66 is the stacking direction, and the positive electrodes 60p and the negative electrodes 60m are staggered with respect to the two cells 62 adjacent to the stacking direction, that is, with the positive electrodes 60p of one cell 62. A plurality of cells 62 are laminated in the stacking direction so that the negative electrode 60 m of the other cell 62 faces each other. As a result, as shown in the conceptual diagram of FIG. 8, when viewed in the stacking direction, the positive electrodes 60p and the negative electrodes 60m of the plurality of cells 62 are alternately arranged.

<3.3 Insertion of positive electrode 60p and negative electrode 60m>
Next, with respect to the two cells 62 adjacent to each other in the stacking direction, the positive electrode 60p of one cell 62 and the negative electrode 60m of the other cell 62 are sandwiched between the two spacers 68 and brought into contact (connection). As shown in FIG. 8, in a state where the positive electrode 60p of one cell 62 and the negative electrode 60m of the other cell 62 face each other, the back of the positive electrode 60p of one cell 62 (separated from the negative electrode 60m). One spacer 68 is arranged in the direction), and the other spacer 68 is arranged behind the negative electrode 60 m of the other cell 62 (direction away from the positive electrode 60p). As a result, the positive electrode 60p of one cell 62 and the negative electrode 60m of the other cell 62 are sandwiched close to each other in the stacking direction, and are connected in a state where contact pressure is generated.

Here, the specific structure of the spacer 68 used for sandwiching the positive electrode 60p and the negative electrode 60m will be described with reference to FIGS. 12A to 16B. In this embodiment, four types of spacers 68 (first to fourth spacers 100 to 106) shown in FIGS. 12A to 16B can be adopted.

(3.3.1 First spacer 100)
The first spacer 100 shown in FIGS. 12A and 12B has a shape in which the direction intersecting the stacking direction is the longitudinal direction and is substantially point-symmetrical with respect to the center of the first spacer 100. That is, the first spacer 100 has the same shape even when inverted by 180 ° in the state shown in FIGS. 12A and 12B. The first spacer 100 is adjacent to the plurality of cells 62 constituting the battery module 10 with respect to the plurality of cells 62 laminated between the cell 62 at one end and the cell 62 at the other end in the stacking direction. It is used to sandwich the positive electrode 60p and the negative electrode 60m between the cells 62.

Specifically, the first spacer 100 has a rectangular spacer body 100a extending in the longitudinal direction. Bolt holes 100b penetrating in the stacking direction are formed at both ends and the center of the spacer body 100a in the longitudinal direction. Further, in the spacer main body 100a, recesses 100c having a size corresponding to the positive electrode 60p and the negative electrode 60m of the cell 62 are formed at locations closer to the center than the bolt holes 100b at both ends.

In this case, one recess 100c is formed in the vicinity of the bolt hole 100b on the one end side on one surface orthogonal to the stacking direction of the spacer body 100a. A sheet 100d made of graphite or the like having good thermal conductivity is fitted in the recess 100c. The exposed surface of the sheet 100d fitted in the recess 100c is covered with a tape 100e having both electrical insulation performance and heat resistance performance. The portion covered with the tape 100e is a portion facing the positive electrode 60p or the negative electrode 60m. Further, the sheet 100d is fitted into the recess 100c by adhering to the recess 100c using an adhesive.

Further, on one surface of the spacer body 100a in the stacking direction, a lightening recess 100f is provided in the vicinity of the bolt hole 100b on the other end side. Further, in the central portion of one surface of the spacer body 100a in the stacking direction, two pins 100g protruding in the stacking direction and two hole portions 100h having a size and a depth corresponding to the two pins 100g are provided. There is.

On the other surface orthogonal to the stacking direction of the spacer body 100a, the other recess 100c in which the sheet 100d whose exposed surface is covered with the tape 100e is fitted and the recess for lightening are located at points symmetrical with respect to one surface. 100f, two pins 100g, and two hole portions 100h are provided, respectively.

(3.3.2 Second spacer 102)
The second spacer 102 shown in FIGS. 13A and 13B is formed between a cell 62 at one end in the stacking direction and another cell 62 stacked on the cell 62 among the plurality of cells 62 constituting the battery module 10. It is used for sandwiching the positive and negative electrodes 60 of the above, or sandwiching the positive and negative electrodes 60 between the cell 62 at the other end in the stacking direction and another cell 62 laminated on the cell 62.

As shown in FIGS. 4 to 8, the positive electrode 60p of the cell 62 at one end in the stacking direction is provided with one positive electrode 72p, and the negative electrode 60m of the cell 62 at the other end in the stacking direction. Is provided with the other negative electrode output terminal 72 m. Therefore, unlike the first spacer 100 of FIGS. 12A and 12B, the second spacer 102 of FIGS. 13A and 13B connects the output terminal 72p to the positive electrode 60p, or connects the output terminal 72m to the negative electrode 60m. It also has a configuration for connecting.

Specifically, the second spacer 102 has a spacer body 102a whose longitudinal direction is a direction intersecting the stacking direction. Bolt holes 102b penetrating in the stacking direction are formed at both ends and the center of the spacer body 102a in the longitudinal direction. Further, on one surface orthogonal to the stacking direction of the spacer body 102a, a recess 102c having the same size as the recess 100c of the first spacer 100 is formed in the vicinity of the bolt hole 102b on the one end side. A sheet 102d whose exposed surface is covered with the tape 102e is fitted into the recess 102c. The sheet 102d and the tape 102e have the same material and shape as the sheet 100d and the tape 100e, respectively.

Further, the other end side of the spacer body 102a bulges outward in the stacking direction. As a result, another recess 102f is provided in the vicinity of the bolt hole 102b on the other end side of the spacer body 102a. Through holes 102i are formed in the other recesses 102f in the stacking direction.

Output terminals 72m and 72p are arranged in the other recesses 102f. In this case, the output terminals 72m and 72p are composed of a plate-shaped portion 110 fitted into the other recess 102f and a terminal portion 112 that is exposed to the outside in the stacking direction by inserting the through hole 102i from the plate-shaped portion 110. ..

Further, in a state where the output terminals 72m and 72p are arranged in the other recesses 102f, the sheet 102d whose exposed surface is covered with the tape 102e is further fitted into the recesses 102f. The sheet 102d is arranged in the recess 102f in order to hold the output terminals 72m and 72p in the recess 102f and hold the positive electrode 60p or the negative electrode 60m of the cell 62.

In the central portion of one surface of the spacer body 102a in the stacking direction, two pins 102g protruding in the stacking direction and two hole portions 102h having a size and a depth corresponding to the two pins 102g are provided. There is.

(3.3.3 Third spacer 104)
Similar to the second spacer 102 of FIGS. 13A and 13B, the third spacer 104 shown in FIGS. 14A and 14B is the cell 62 at one end in the stacking direction among the plurality of cells 62 constituting the battery module 10. The positive and negative electrodes 60 are sandwiched between the cells 62 and the other cells stacked in the cell 62, or between the cell 62 at the other end in the stacking direction and the other cells 62 stacked in the cell 62. It is used for sandwiching the positive and negative electrodes 60 and the like. Further, the third spacer 104 also has a configuration for connecting the output terminal 72p to the positive electrode 60p or connecting the output terminal 72m to the negative electrode 60m.

Specifically, the third spacer 104 has a spacer body 104a whose longitudinal direction is a direction intersecting the stacking direction. Bolt holes 104b penetrating in the stacking direction are formed at both ends and the center of the spacer body 104a in the longitudinal direction. Further, on one surface orthogonal to the stacking direction of the spacer main body 104a, recesses 104c having the same size as the recesses 100c of the first spacer 100 are formed in the vicinity of the bolt holes 104b at both ends. A sheet 104d whose exposed surface is covered with tape 104e is fitted into one of the two recesses 104c. The sheet 104d and the tape 104e have the same material and shape as the sheet 100d and the tape 100e, respectively.

Two pins 104g protruding in the stacking direction and two hole portions 104h having a size and a depth corresponding to the two pins 104g are provided in the central portion of one surface of the spacer main body 104a in the stacking direction. On the other hand, on the other surface of the spacer body 104a orthogonal to the stacking direction, another recess 104f for arranging the output terminals 72m and 72p (see FIGS. 4 to 8) is provided.

(3.3.4 Fourth spacer 106)
A plurality of fourth spacers 106 shown in FIGS. 15 to 16B are laminated between the cell 62 at one end and the cell 62 at the other end in the stacking direction, similarly to the first spacer 100 in FIGS. 12A and 12B. Cell 62 is used to sandwich the positive and negative electrodes 60 between two adjacent cells 62.

Specifically, the fourth spacer 106 has a spacer body 106a whose longitudinal direction is a direction intersecting the stacking direction. Bolt holes 106b penetrating in the stacking direction are formed at both ends and the center of the spacer body 106a in the longitudinal direction. Further, on one surface of the spacer body 106a in the stacking direction, recesses 106c having a size corresponding to the positive electrode 60p or the negative electrode 60m of the cell 62 are formed at both ends on the bolt holes 106b side. Further, in the central portion of one surface, two pins 106g protruding in the stacking direction and two hole portions 106h having a size and a depth corresponding to the two pins 106g are provided.

On the other surface orthogonal to the stacking direction of the spacer body 106a, a recess 106c having a size corresponding to the positive electrode 60p or the negative electrode 60m of the cell 62 is formed at one end on the bolt hole 106b side. Further, in the central portion of the other surface, two holes 106 g protruding in the stacking direction and two holes having a size and a depth corresponding to the two pins 106 g at a position symmetrical with respect to the central portion of one surface. A portion 106h is formed.

Then, in the fourth spacer 106, the sheet 106d is fitted in each recess 106c. The exposed surface of each sheet 106d is covered with tape 106e. In the spacer main body 106a, two sheets 106d are arranged in two recesses 106c at one end on the bolt hole 106b side. Therefore, the exposed surfaces of the two sheets 106d are covered with one tape 106e. The sheet 106d has the same material and shape as the sheet 100d. Further, the tape 106e has the same material as the tape 100e.

(3.3.5 Specific example of sandwiching the electrode 60)
The sandwiching of the positive and negative electrodes 60 using the spacer 68 is as shown in the conceptual diagram of FIG. 8, but in reality, as described below, the first to fourth spacers 100 to 106 are used. The positive electrode 60p and the negative electrode 60m of the plurality of cells 62 stacked in the stacking direction are sandwiched.

First, using each cell 62 of FIGS. 10B and 11B, as shown in FIG. 17, the positive electrode 60p of one adjacent cell 62 and the negative electrode 60m of the other cell 62 are staggered. A plurality of cells 62 are laminated in the stacking direction. As a result, as shown in FIG. 18, the positive electrode 60p and the negative electrode 60m of the two cells 62 come into contact with each other (overlap) in the stacking direction.

Next, the positive electrode 60p of one cell 62 is pressed against the negative electrode 60m side of the other cell 62 by the sheet 100d of the first spacer 100, and the other cell is pressed by the sheet 100d of the other first spacer 100. The negative electrode 60m of 62 is pressed against the positive electrode 60p side of one cell 62. As a result, the positive electrode 60p of one cell 62 and the negative electrode 60m of the other cell 62 are sandwiched in the stacking direction at an arbitrary contact pressure. The contact pressure can be adjusted by changing the thickness of the tape 100e or the like.

In this case, the two pins 100g of one first spacer 100 are fitted into the two hole portions 100h of the other first spacer 100, and the other is fitted into the two hole portions 100h of one first spacer 100. Two pins 100g of the first spacer 100 are fitted. As a result, one surface of one first spacer 100 and the other surface of the other first spacer 100 come into surface contact with each other. As a result, it is possible to maintain the holding state of the positive electrode 60p and the negative electrode 60m. In addition, the electrical connection state can be secured and the contact resistance value can be reduced.

The positive electrode 60p and the negative electrode 60m are bent into a desired shape by bending. Therefore, for example, in a state where one electrode 60 is covered with the other electrode 60 (superposed state), the positive electrode 60p of one cell 62 and the negative electrode 60m of the other cell 62 may be sandwiched in the stacking direction. desirable.

By sandwiching the positive and negative electrodes 60 between the two adjacent cells 62 in this way, the plurality of cells 62 are electrically connected in series to form the cell aggregate 64.

Next, as shown in FIGS. 19 and 20, the second spacer 102 is attached to the cell 62 arranged at one end of the cell assembly 64 in the stacking direction and the cell 62 arranged at the other end in the stacking direction. Alternatively, by arranging the third spacer 104, the output terminal 72p is connected to the positive electrode 60p of the cell 62 at one end, and the output terminal 72m is connected to the negative electrode 60m of the cell 62 at the other end.

First, as shown in FIG. 19, the second spacer 102 is arranged in the cell 62 at one end in the stacking direction, and the output terminal 72p and the positive electrode 60p of the cell 62 at one end are connected. In this case, the insertion hole 116 may be formed in advance in the positive electrode 60p. As a result, when the positive electrode 60p is bent in advance in a U shape and the terminal portion 112 of the output terminal 72p is inserted into the insertion hole 116, the output terminal 72p and the positive electrode 60p are connected. The negative electrode 60m of the cell 62 at one end is sandwiched by the sheet 100d of the first spacer 100 and the sheet 102d of the second spacer 102 together with the positive electrode 60p of another cell 62 adjacent in the stacking direction.

Further, as shown in FIG. 20, a third spacer 104 is arranged in the cell 62 at the other end in the stacking direction to connect the output terminal 72 m and the negative electrode 60 m of the cell 62 at the other end. In this case, as shown in FIGS. 20 and 21, the sheet 104d of the third spacer 104 and the sheet 100d of the first spacer 100 are overlapped with the negative electrode 60m of the cell 62 at the other end and the output terminal 72m. Then, the negative electrode 60 m and the output terminal 72 m are sandwiched in the stacking direction.

Also in the cases of FIGS. 19 to 21, the two pins 102g and 104g of the second spacer 102 or the third spacer 104 fit into the two holes 100h of the first spacer 100, and the second spacer 102 or the third spacer The two pins 100g of the first spacer 100 are fitted into the two holes 102h and 104h of the 104. As a result, the surface of the second spacer 102 or the third spacer 104 facing the first spacer 100 and the surface of the first spacer 100 facing the second spacer 102 or the third spacer 104 come into surface contact with each other. As a result, the sandwiched state between the output terminal 72p and the positive electrode 60p and the sandwiched state between the output terminal 72m and the negative electrode 60m can be reliably maintained. Even in this case, it is desirable to sandwich one of the output terminal 72 m and the negative electrode 60 m in the stacking direction with one of them covered with the other (superposed state).

In the above description, the fourth spacer 106 may be used instead of the first spacer 100, or the first spacer 100 and the fourth spacer 106 may be used in combination. In any case, the positive and negative electrodes 60 of the plurality of cells 62 stacked in the stacking direction can be sandwiched.

<Temporary fixing of spacer 68 with 3.4 bolts 122 and nuts 124>
In this way, the positive and negative electrodes 60 of the plurality of cells 62 are sandwiched by the plurality of spacers 68 (first to fourth spacers 100 to 106) in the stacking direction, and as shown in FIG. 22, each spacer 68 The bolt 122 is inserted into the bolt holes 100b to 106b of the above and screwed into the nut 124. As a result, as shown in FIG. 23, each spacer 68 is temporarily fixed in the stacking direction.

<3.5 Installation of BMS board 74>
Next, as shown in FIG. 24, a portion where the positive and negative electrodes 60 are sandwiched (a portion where the positive electrode 60p and the negative electrode 60m are connected) and a positive electrode 60p (output) of the cell 62 at one end in the stacking direction. The BMS substrate 74 is connected to the terminal 72p) and the negative electrode 60m (output terminal 72m) of the cell 62 at the other end in the stacking direction. The BMS substrate 74 has a configuration in which a plurality of plate-shaped connection electrodes 74b are provided on the bottom surface of one substrate 74a.

In this case, the BMS substrate 74 covers each spacer 68 with the plurality of connection electrodes 74b facing each spacer 68. As a result, each connection electrode 74b is connected to the connection point between the positive electrode 60p and the negative electrode 60m, the positive electrode 60p of the cell 62 at one end, and the negative electrode 60m of the cell 62 at the other end. In this state, the temporarily fixed bolt 122 and the nut 124 are further screwed together, and the spacers 68 are tightened in the stacking direction. As a result, the positive and negative electrodes 60 (positive electrode 60p, negative electrode 60m) and the connecting electrode 74b are firmly sandwiched.

<Arrangement of 3.6 cell aggregate 64 in case 70>
Next, as shown in FIG. 25, the cell assembly 64 is placed in the case 70, and each spacer 68, each output terminal 72m, 72p, and the BMS substrate 74 are exposed to the outside. Since the case 70 is open in two directions, the cell assembly 64 is fixed to the case 70 with a tape 126 having electrical insulation performance and heat resistance performance. As a result, the battery module 10 shown in FIGS. 4 to 7 is completed.

In addition, in FIGS. 17 to 25, the case where the battery module 10 of FIG. 4 is manufactured has been described as an example, but the battery modules 10 of FIGS. 5 to 7 also have output terminals 72m and 72p and the output terminals 72m. By changing the spacer 68 that holds 72p, it can be manufactured according to the above manufacturing procedure.

<3.7 Loading the battery module 10 into the battery case 30>
As shown in FIGS. 26 to 29, the battery module 10 manufactured as described above is provided in the lower case 78 of FIG. 26, the intermediate case 80 of FIGS. 27 and 28, and the upper case 82 of FIG. 29. Each is loaded.

In the case of the lower case 78 of FIG. 26, the length of the lower case 78 is inside the wall portion 78b of the lower case 78 with the BMS board 74 of the battery module 10 oriented in the horizontal direction (sideways). Arrange in the direction (front-back direction of FIGS. 1 to 3). In this case, the plurality of battery modules 10 are electrically connected by inserting the bolt 132 into the through hole 130 formed in the output terminals 72m and 72p between the two adjacent battery modules 10 and screwing the bolt 132 into the nut 134. Can be connected in series with.

In the case of the intermediate case 80 of FIGS. 27 and 28, with the BMS substrate 74 of the battery module 10 facing upward (standing), inside the frame 80b of the intermediate case 80, the horizontal direction of the intermediate case 80. Arrange in the front-rear direction and the left-right direction of FIGS. 1 to 3. In this case, the plurality of battery modules 10 are electrically connected by inserting the bolts 132 into the through holes 130 of the positive and negative output terminals 72m and 72p and screwing them with the nuts 134 between the two adjacent battery modules 10. Can be connected in series. Further, in a state where the plurality of battery modules 10 are arranged, the front frame 80b and the rear frame 80b are connected by a plurality of frames 136 using a plurality of bolts 84, whereby a plurality of battery modules are connected. 10 can be held in the intermediate case 80.

In the case of the upper case 82 of FIG. 29, the BMS substrate 74 of the battery module 10 is facing upward (upright state), and inside the frame body 82b of the upper case 82, the upper case 82 is in the horizontal direction (FIG. 1). ~ Arrange in the front-back direction and the left-right direction in FIG. In this case, the plurality of battery modules 10 are electrically connected by inserting the bolts 132 into the through holes 130 of the positive and negative output terminals 72m and 72p and screwing them with the nuts 134 between the two adjacent battery modules 10. Can be connected in series.

As shown in FIG. 3, the lower case 78, the intermediate case 80, and the upper case 82 in which the plurality of battery modules 10 are arranged are fixed in the vertical direction by using bolts 84. As a result, as shown in FIG. 2, the battery 28 composed of the plurality of battery modules 10 is housed in the battery case 30. Such a battery case 30 is loaded on the electric vehicle 14.

The arrangement and loading method of the battery modules 10 shown in FIGS. 26 to 29 are examples. In the present embodiment, other arrangements and loading methods are provided for the lower case 78, the intermediate case 80, and the upper case 82. Of course, it may be adopted.

[4. Effect of this embodiment]
As described above, in the battery module 10 according to the present embodiment, a plurality of cells 62 having positive and negative electrodes 60 (positive electrode 60p, negative electrode 60m) are laminated, and each electrode 60 of the plurality of cells 62 is connected. It has a cell assembly 64 to be composed. In this case, a plurality of cells 62 are stacked in the stacking direction so that the positive and negative electrodes 60 are staggered between the two cells 62 adjacent to each other in the stacking direction. Further, the cell assembly 64 includes a plurality of spacers 68 (first to fourth spacers 100 to 106). In this case, of the two adjacent cells 62, the positive electrode 60p of one cell 62 and the negative electrode 60m of the other cell 62 are connected by sandwiching them with a plurality of spacers 68, whereby the plurality of cells 62 are connected in series. Connect.

As described above, since the simple connection structure is such that the positive and negative electrodes 60 of the two cells 62 adjacent to each other in the stacking direction are sandwiched between the plurality of spacers 68 and connected, the cells 62 can be easily replaced and maintained. At the same time, the man-hours and costs required for replacement can be reduced.

In this case, bolt holes 100b to 106b through which the bolt 122 is inserted are formed in the stacking direction at both ends in the longitudinal direction intersecting the stacking direction of the plurality of spacers 68. As a result, the bolt 122 through which the bolt holes 100b to 106b are inserted and the nut 124 are screwed together, so that the holding state of the positive and negative electrodes 60 can be reliably maintained. Further, if the fastened state of the bolt 122 and the nut 124 is released, the positive and negative electrodes 60 are released from the narrowed state, so that the cell 62 can be easily replaced (attached / detached). As a result, it is possible to replace only the cell 62 to be replaced.

Further, at one end of the cell assembly 64 in the stacking direction, one (positive electrode) output terminal 72p connected to the positive electrode 60p of the cell 62 arranged at the one end is provided. Further, at the other end of the cell assembly 64 in the stacking direction, the other (negative electrode) output terminal 72m connected to the negative electrode 60m of the cell 62 arranged at the other end is provided. As a result, the output terminals 72m and 72p of the plurality of battery modules 10 can be electrically connected in series to easily configure the battery 28.

Further, it is desirable that each electrode 60 of the plurality of cells 62 is made of a flexible conductive member. As a result, the positive electrode 60p and the negative electrode 60m of the two adjacent cells 62 can be easily held in a superposed state. Further, the contact area between the positive electrode 60p and the negative electrode 60m can be increased to facilitate pressure contact. As a result, it is possible to reduce the contact resistance value between the positive electrode 60p and the negative electrode 60m.

In this case, the plurality of spacers 68 sandwich the positive electrode 60p and the negative electrode 60m in a state where the positive electrode 60p of one cell 62 and the negative electrode 60m of the other cell 62 are bent or overlapped. You can connect with. This eliminates the need for welding, crimping, and bonding such as spot welding, so that the battery module 10 can be easily assembled. In particular, if the tip portion of one electrode 60 is folded back and bent so as to surround the other electrode 60, the above effect can be easily obtained.

Further, in the battery module 10, the positive electrode 60p of the cell 62 arranged at the connection point between the positive electrode 60p of one cell 62 and the negative electrode 60m of the other cell 62 and one end of the cell assembly 64 in the stacking direction is provided. And a BMS substrate 74 (cell voltage detection substrate) for detecting the voltage of a plurality of cells 62, which is connected to the negative electrode 60 m of the cell 62 arranged at the other end of the cell assembly 64 in the stacking direction. Further, the BMS substrate 74 may be arranged on the upper part of the plurality of spacers 68. As a result, the voltage of each cell 62 can be easily detected, so that the maintenance of each cell 62 becomes easy.

Further, the battery module 10 may further have a case 70 (storage body) for storing the cell assembly 64. This facilitates handling such as carrying the battery module 10.

In this case, it is sufficient that the plurality of battery modules 10 are arranged in the horizontal direction and stored in the battery case 30 in a state of being stacked in multiple stages in the vertical direction. As a result, it is possible to realize a storage structure of the battery module 10 having an excellent design that matches the shape of the body frame 18 of the electric vehicle 14.

The number of battery modules 10 housed in the battery case 30 is such that the number of battery modules 10 housed in the lower side of the battery case 30 is larger than the number of battery modules 10 housed in the upper side of the battery case 30. The more you have, the better. As a result, the center of gravity of the electric vehicle 14 such as a two-wheeled vehicle can be lowered, and the storage structure can be adapted to the shape of the storage location of the battery 28 in the electric vehicle 14.

Further, by providing the positive electrode 60p and the negative electrode 60m in which the plurality of cells 62 extend in one direction, the positive and negative electrodes 60 are sandwiched between the two adjacent cells 62 when the plurality of cells 62 are stacked. It will be easier.

In this case, it is desirable that the plurality of cells 62 are laminated battery cells. Thereby, the battery module 10 can be easily configured by using the cell 62 of the thin lithium ion battery or the lead battery.

Further, in the storage structure of the battery module 10 according to the present embodiment, the battery module 10 is a cell formed by stacking a plurality of cells 62 having positive and negative electrodes 60 and connecting the electrodes 60 of the plurality of cells 62. It has an aggregate 64. In this case, the plurality of battery modules 10 are housed in the battery case 30 in a state where they are arranged in the horizontal direction and are stacked in multiple stages in the vertical direction.

As a result, the effects of the above-mentioned horizontal arrangement and the multi-tiered stacking in the vertical direction can be easily obtained.

Even in this case, if the number of battery modules 10 stored in the lower stage side of the battery case 30 is larger than the number of battery modules 10 stored in the upper stage side of the battery case 30, the above-mentioned upper stage side and lower stage side can be obtained. The effect due to the difference in the number of arrangements between the two can be easily obtained.

Further, if the battery case 30 has a saddle shape, a trapezoidal shape, or a convex shape, the battery case 30 having an optimum structure suitable for the shape of the body frame 18 of the electric motorcycle can be realized.

It should be noted that the present invention is not limited to the above-described embodiment, and it goes without saying that various configurations can be adopted based on the contents described in this specification.

10 ... Battery module 28 ... Battery 30 ... Battery case 60 ... Electrode 60m ... Negative electrode 60p ... Positive electrode 62 ... Cell 64 ... Cell aggregate 68 ... Spacer 100 ... First spacer 102 ... Second spacer 104 ... Third spacer 106 ... 4th spacer

Claims (9)

A plurality of plate-shaped cells, a plurality of the cells are stacked in the thickness direction of the cell, electrically connected to configured cell collection the cells adjacent to each other in the stacking direction of the plurality of the cells have a, each of the plurality of said cell has a rectangular end face at one end in a direction perpendicular to the stacking direction, the end surface, contact intervals in the long side direction of the rectangular of the end face a battery module is a plate-shaped positive and negative electrodes that are provided have,
Wherein between the two said cells adjacent in the stacking direction, are arranged so that the negative electrode face each other of the positive electrode and the other cells of the one cell,
The one end portion of each of the cells of the multiple, substantially rectangular spacer extending toward the longitudinal direction to the long side direction of the rectangular said end surface is arranged,
Bolt holes through which the fastening bolts of the spacers are inserted are formed at both ends and the center of each of the plurality of spacers in the longitudinal direction in the stacking direction.
For each of the plurality of cells, one of the positive and negative electrodes of the cell is arranged between the central portion and one end portion of the spacer in the longitudinal direction, and between the central portion and the other end portion , The other of the positive and negative electrodes of the cell is arranged ,
Of the two said cells adjacent in the stacking direction, sandwiched between two of the spacers adjacent to the stacking direction by the fastening force of the fastening bolt and the negative electrode of the positive electrode and the other side of the cell of one cell By connecting with, multiple cells can be connected in series.
Further, at one end of the cell assembly in the stacking direction, one output terminal connected to the positive electrode of the cell arranged at one end of the cell assembly is provided.
A battery module in which the other end of the cell assembly in the stacking direction is provided with the other output terminal connected to the negative electrode of the cell arranged at the other end of the cell assembly . In the battery module according to claim 1,
A battery module in which each electrode of the plurality of cells is made of a flexible conductive member. In the battery module according to claim 2.
The plurality of spacers are in a state where the positive electrode of the one cell and the negative electrode of the other cell are bent, or one of the positive electrode of the one cell and the negative electrode of the other cell. A battery module in which an electrode is covered with the other electrode and overlapped with each other, and the positive electrode and the negative electrode are sandwiched and connected. In the battery module according to any one of claims 1 to 3.
At least two recesses are formed in the plurality of spacers so as to face the positive electrode and the negative electrode.
A heat conductive sheet is fitted in at least two of the recesses.
The exposed surface of the sheet is covered with a tape having both electrical insulation performance and heat resistance performance.
By pressing the sheet provided on one of the spacers against the positive electrode of the one cell and pressing the sheet provided on the other spacer against the negative electrode of the other cell, the positive electrode of the one cell is pressed. A battery module that connects an electrode and the negative electrode of the other cell. In the battery module according to any one of claims 1 to 4.
The connection point between the positive electrode of the one cell and the negative electrode of the other cell, the positive electrode of the cell arranged at one end of the cell assembly in the stacking direction, and the stacking direction of the cell assembly. It is connected to the negative electrode of the cell arranged at the other end of the cell, and further has a cell voltage detection substrate for detecting the voltage of the plurality of cells.
A plurality of connection electrodes are provided on the bottom surface of the cell voltage detection substrate on the spacer side.
The plurality of connection electrodes are the positive electrode of the cell arranged at one end, the negative electrode of the cell arranged at the other end, and the positive electrode of the one cell sandwiched between the plurality of spacers. Connected to the electrode and the negative electrode of the other cell,
By inserting the fastening bolt into the bolt hole, the plurality of connection electrodes and the positive and negative electrodes of the plurality of cells are sandwiched by the plurality of spacers.
A plurality of the cell voltage detection substrates are arranged on the plurality of spacers.
A battery module in which the plurality of cell voltage detection substrates are arranged so as to cover the plurality of spacers and the positive and negative electrodes of the plurality of cells from above. In the battery module according to any one of claims 1 to 5.
A battery module further comprising a storage body for storing the cell assembly. In the battery module according to claim 6,
The plurality of battery modules are rectangular parallelepipeds and are housed in a plurality of cases having different shapes in a state of being arranged horizontally or vertically.
A battery module in which a plurality of the above cases are stacked in multiple layers in the vertical direction to form a battery case. In the battery module according to claim 7.
The number of the battery modules housed in the battery case is such that the number of battery modules housed in the lower case of the battery case is larger than the number of battery modules housed in the upper case of the battery case. Many,
Further, the battery modules housed in the lower case are a plurality of battery modules arranged in the horizontal direction. In the battery module according to any one of claims 1 to 8.
The plurality of the cells are battery modules, which are laminated battery cells.

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