JP6782830B2 - Battery module - Google Patents

Description

The present invention relates to an assembled battery in which a plurality of flat square secondary cells are connected, and a bus bar for the assembled battery.

An assembled battery formed by connecting a plurality of flat square secondary batteries (hereinafter referred to as a cell) is a fixing member (hereinafter referred to as a fixed member) mainly composed of an insulating member such as engineering plastic that holds the plurality of cells and the cells. A constant binding force (hereinafter referred to as a side plate) that is a restraining member (hereinafter referred to as a side plate) in which an end plate (hereinafter referred to as an end plate) mainly composed of a rigid metal body and an end plate (hereinafter referred to as an end plate) are stacked in parallel with a wide area flat surface and restrained (hereinafter referred to as fixed binding). It is maintained as a structure by imparting (hereinafter referred to as "binding force"). As shown in Patent Document 1, flat square secondary batteries use a metal flat plate called a bus bar for electrical connection of the batteries.

Due to the required performance and necessity, it is inevitable that the assembled battery mounted on an automobile or the like is repeatedly charged and discharged with a large current, and as a result, the wide-area flat surface of the single battery expands and contracts due to a change in the internal pressure of the single battery. Is prompted. Further, since the assembled battery is mainly mounted on an automobile, there is a concern that the generation of stress on the electrode portion of the cell cell due to the vibration shock may cause fatigue failure or plastic deformation. For this reason, the bass bar is provided with a bent portion for the purpose of absorbing vibration and shock to alleviate the problem.

Japanese Unexamined Patent Publication No. 2014-075179

As the material of the bus bar, a metal material using a dissimilar metal joint is mainly mentioned. As the dissimilar metals, a metal mainly composed of aluminum and a metal mainly composed of copper are often used. Since a bus bar having a bent portion is stressed when providing a bent portion, conventionally, a joint portion between dissimilar metals has been provided so as to avoid the bent portion.

However, in this case, a space for providing a joint is required, and there is a problem that it is difficult to reduce the height of the bass bar.

Further, such a joint has a problem that it has a low resistance to peeling against stress.

The means for solving the above problems are as follows, for example.

A bus bar having a plurality of secondary batteries, a pair of flat portions, and a bent portion arranged between one flat portion and the other flat portion of the pair of flat portions, and connecting the plurality of secondary batteries to each other. In the battery module provided with, the bus bar is a clad material in which dissimilar metals are bonded to each other, and the joint portion which is a joint end portion between dissimilar metals is a flat portion of one of the flat portions and the other flat portion. Each of the bus bars has a welded portion to be joined to the terminal of the battery, and the bent portion is a pair of rising bent portions rising from each of the pair of flat portions and the pair of rising bent portions. When the bus bar is viewed from the direction of the battery lid, the joint portion is formed from the flat portion of one of the pair of flat portions via the bent portion. , to the other of the flat portion of the pair of flat portions, linearly provided, the battery module wherein weld characterized that you have provided at a position which does not overlap with the junction of the flat portion ..

According to the present invention, even if a clad material is used and a bent portion is provided, the height can be suppressed (reduced height), and a stress-resistant bass bar can be provided.

External perspective view of the assembled battery 1 FIG. 3 is a perspective view showing a state in which a part of the assembled battery shown in FIG. 1 is disassembled. Perspective view of the cell 2 The figure which looked at the bus bar of Example 1 from the direction of a battery lid The figure which looked at the bus bar of Example 1 from the arrangement direction The view of the bus bar of Example 1 from the width direction. Perspective view of the bus bar 9 of Comparative Example 1 View of the bus bar of Comparative Example 1 from the direction of the battery lid The figure which looked at the bus bar of the comparative example 1 from the arrangement direction View of the bus bar of Comparative Example 1 from the width direction The figure which looked at the bus bar of Example 2 from the direction of a battery lid The figure which looked at the bus bar of Example 2 from the arrangement direction The view of the bus bar of Example 2 from the width direction.

Hereinafter, embodiments of the assembled battery according to the present invention will be described with reference to the drawings.

FIG. 1 is an external perspective view of the assembled battery 1, and FIG. 2 is a perspective view showing a partially disassembled state of the assembled battery 1 shown in FIG.

(Example 1)
The assembled battery 1 includes a plurality of stacked cell batteries 2, a pair of end holders 3 provided at the ends of the plurality of stacked cells, and a plurality of cells individually interposed between the plurality of cell cells 2. Along the width direction (Y direction) both ends of the cell holder 4, the end plates 5 arranged at both ends of the array direction (X direction) of the plurality of cell cells 2 and sandwiched from both sides in the array direction. It has a pair of side plates 6 that are arranged and extend from one end to the other in the arrangement direction and are fixed to the pair of end plates 5. The end plate 5 and the side plate 6 are fixed by a fixing member 7 such as a rivet.

As the arranged cell batteries 2, a square flat battery as shown in FIG. 3 described later can be used. The cell 2 has a pair of wide surfaces 201w, a pair of narrow surfaces 201n, a lid 202, and a can bottom 201b. The cell 2 is arranged in the arrangement direction with the wide surfaces 201w facing each other. A plurality of cell cell 202 lids 202 are arranged on one side in the height direction (Z direction) of the arranged cell cells 2, and the positive electrode terminal 203 and the negative electrode terminal 204 provided on the lids 202 of the adjacent cell cells 2 are provided. Is connected by the bus bar 9. Therefore, the cell 2 is arranged so that the positive electrode terminal and the negative electrode terminal alternate in the width direction.

The bus bar 9 is partitioned and provided in the bus bar case 8 provided so as to face the lid of the cell 2. The bus bar case 8 has a hole, through which the terminal of the cell and the bus bar 9 are connected.

FIG. 3 is a perspective view of the cell 2.

The cell 2 has a pair of wide surfaces 201w, a pair of narrow surfaces 201n, a lid 202, and a can bottom 201b. The lid 202 is provided with a positive electrode terminal 203 and a negative electrode terminal 204. The positive electrode terminal 203 and the negative electrode terminal 203 have a flat surface connected to the bus bar 9. The lid 202 may also be provided with a gas discharge valve 202b, an electrolytic solution injection hole 202, or the like.

FIG. 4 is a view of the bus bar of the first embodiment viewed from the battery lid direction, FIG. 5 is a view of the bus bar of the first embodiment viewed from the array direction, and FIG. 6 is a view of the bus bar of the first embodiment viewed from the width direction. ..

The bus bar 9 has a pair of flat portions 912 and 911 connected to the positive electrode terminal and the negative electrode terminal, respectively, and bent portions 910 and 914 provided between the pair of flat portions 912 and 911.
The pair of flat portions 912 and 911 are formed between a pair of rising bending portions 910 rising from the flat portion 912, a U-shaped bending portion 914 connecting the pair of rising bending portions, and in some cases, between the U-shaped bending portion 914 and the rising bending portion. It is connected by the provided middle part. The height of the bus bar 9 can be lowered by not having an intermediate portion or by having a small intermediate portion. When there is no intermediate portion, the pair of rising bending portions 910 are directly connected by the U-shaped bending portion 914.

Here, the rising and bending portion 910 may stand up perpendicular to the surface of the flat portion, or may stand up at an angle. The U-shaped bent portion may be bent in a state of having corners other than the U-shape.

As the bus bar 9, a clad material obtained by joining dissimilar metals to each other can be used. As the material, for example, a metal whose main material is aluminum and a metal whose main material is copper can be used, and each material is joined at a joint. It is preferable that both ends (joining portions) of the joining ends of dissimilar metals are arranged in each of the pair of flat portions. In the first embodiment, the joint portion 916 is provided linearly from one flat portion 912 toward the other flat portion 911 via bent portions 914 and 910.

Since the joint portion is a portion where dissimilar metals are bonded to each other, the peeling resistance to stress is lower than that of other locations. Therefore, conventionally, such a joint portion has been provided at a location other than the bent portion, for example, an intermediate portion 913, so that stress applied during the production of the bent portions 914 and 910 is not applied. However, when a joint is provided in the middle. Since the length of the intermediate portion must be increased, there is a problem that the height of the bus bar 9 becomes large. However, by arranging both ends (joints) of the joint ends of dissimilar metals in each of the pair of flat portions as in the present invention, the risk of peeling is reduced as compared with the case where the joints are provided in the bent portions. Therefore, the height of the bus bar 9 can be lowered as compared with the case where the joint portion is provided in the intermediate portion.

In addition, stress is often applied to the bus bar 9 in the arrangement direction of the cells. Therefore, the joint portion can be made to have a structure that is less likely to be peeled off by providing an angle rather than vertical with respect to stress as compared with the case where the joint portion is provided perpendicular to the arrangement direction.

By arranging both ends (joints) of the joint ends of dissimilar metals on each of the pair of flat portions, it is possible to provide an angle rather than vertical with respect to stress, and a structure resistant to stress can be obtained. ..

As a method of joining dissimilar metals to each other, for example, an aluminum plate and a copper plate are butted against each other to be clad, punched so that the joint portion is oblique to the plate of the bus bar 9 as shown in the figure, and then a bent portion is formed. Manufactured by letting.

In addition, known techniques can be used. For example, aluminum and copper are surface-bonded by pressure, and the bonding is strengthened by heat treatment. It can be manufactured by cutting out a plate-shaped member having a joint portion from the joined material and forming a bent portion.

The bus bar 9 is connected to the cell by welding the flat portion 912 and the positive electrode terminal 203 and welding the flat portion 911 and the negative electrode terminal 912 (welded portion 917). Welding of the flat portion 912 and the positive electrode terminal is preferably performed at a position in the flat portion where dissimilar metals of the bass bar are not mixed, and the connection between the flat portion 911 and the negative electrode terminal is also the same. The bus bar 9 has a welded portion to be welded to the terminal. The welded portion is provided at a position on the flat portion side of the joint portion 916 so as not to overlap with the joint portion 916.

(Comparative Example 1)
Here, a comparative example is shown as a comparison with Example 1.

FIG. 7 is a perspective view of the bus bar 9 of Comparative Example 1.

FIG. 8 is a view of the bus bar of Comparative Example 1 viewed from the battery lid direction, FIG. 9 is a view of the bus bar of Comparative Example 1 viewed from the arrangement direction, and FIG. 10 is a view of the bus bar of Comparative Example 1 viewed from the width direction. ..

The bus bar 9 is made of a clad material of a metal whose main material is aluminum and a metal whose main material is copper, as in the first embodiment, and is the same as the embodiment except for the position of the joint portion 916.

The joint portion 916 is provided in the intermediate portion 913. By providing the joint portion 916 at a position other than the bent portions 910 and 914, it is possible to reduce the risk that the joint portion will be peeled off when the bent portions 910 and 914 are formed. However, there is a problem that the height of the bus bar 9 becomes high due to the increase in the intermediate portion by providing the joint portion 916 in the intermediate portion 913. Further, the joint portion is provided substantially perpendicular to the stress applied when the battery is used. On the other hand, in Example 1, since the stress is at an angle rather than vertical, the peeling strength is high.

(Example 2)
11 is a view of the bus bar of the second embodiment viewed from the battery lid direction, FIG. 12 is a view of the bus bar of the second embodiment viewed from the array direction, and FIG. 13 is a view of the bus bar of the second embodiment viewed from the width direction. ..

The bus bar 9 is made of a clad material of a metal whose main material is aluminum and a metal whose main material is copper, as in the first embodiment, and is the same as the embodiment except for the position of the joint portion 916.

The joint portion 916 is arranged in each of the pair of flat portions as in the first embodiment. Therefore, the risk of peeling can be reduced as compared with the case where the joint portion is provided in the bent portion, and the height of the bus bar 9 can be lowered as compared with the case where the joint portion is provided in the intermediate portion.

1 set battery 2 cell battery 3 end holder 4 cell cell holder 5 end plate 6 side plate 7 fixing member 8 bus bar case 9 bus bar 201w wide surface 201n narrow surface 202 lid 201b can bottom 203 positive electrode terminal 204 negative electrode terminal 910 bent part (rising bending) Department)
911, 912 Flat part 913 Intermediate part 914 Bent part (U-shaped bent part)
916 Joint 917 Weld

Claims (2)

With multiple rechargeable batteries
A bus bar having a pair of flat portions and a bent portion arranged between one flat portion and the other flat portion of the pair of flat portions and connecting the plurality of secondary batteries to each other.
In the battery module equipped with
The bus bar is a clad material in which dissimilar metals are bonded to each other, and a joint portion which is a joint end portion between dissimilar metals is arranged in each of the one flat portion and the other flat portion .
The bus bar has a welded portion that is joined to the terminal of the battery.
The bent portion has a pair of rising bent portions that rise from each of the pair of flat portions, and a U-shaped bent portion that connects the pair of rising bent portions to each other.
When the bus bar is viewed from the direction of the battery lid, the joint portion is formed from the flat portion of one of the pair of flat portions through the bent portion, and the joint portion of the other of the pair of flat portions. It is provided in a straight line up to the flat part,
The weld cell module characterized that you have provided at a position which does not overlap with the junction of the flat portion. In the battery module according to claim 1 ,
The dissimilar metal is a battery module characterized by being composed of a metal whose main material is aluminum and a metal whose main material is copper, respectively.

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