JP2019036386A - Battery pack - Google Patents

Abstract

To suppress cracks from being generated on a flexible substrate due to expansion and contraction of a battery module, in a battery pack.SOLUTION: A battery pack is configured to comprises: a convex bus bar Bb that has a first connection part C1 connected with a terminal T of one battery module Bm of adjacent two battery modules Bm, a second connection part C2 connected with a terminal T of the other battery module Bm, a flat part F, a first deformation part D1 connecting the first connection part C1 and the flat part F, and a second deformation part D2 connecting the second connection part C2 and the flat part F; and a flexible substrate FPC that has a main body part Bd, and a projection Pr connected with the flat part F. The projection Pr is provided for each adjacent two battery modules Bm at least at one of sides along an adjacent direction of the adjacent two battery modules Bm, of the main body part Bd.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a battery pack.

Some existing battery packs include a plurality of battery modules arranged adjacent to each other and a flexible substrate connected to each terminal of each battery module.
As related techniques, for example, there are Patent Documents 1 and 2.

JP 2010-257775 A JP 2014-022287 A

  However, in the battery pack described above, stress is applied to the connection portion between the terminal of the battery module and the flexible substrate due to the expansion and contraction of each battery module causing the respective terminals of each battery module to move away from each other or approach each other. There is a risk of cracks.

  Therefore, an object according to one aspect of the present invention is to provide a battery pack capable of suppressing cracks in a flexible substrate due to expansion and contraction of a battery module.

The battery pack which is one form which concerns on this invention is provided with a convex-shaped bus bar and a flexible substrate.
The convex bus bar is connected to the first connection portion connected to the terminal of one of the two adjacent battery modules and the terminal of the other battery module of the two adjacent battery modules. A second connecting portion, a flat portion, a first deforming portion that connects the first connecting portion and the flat portion, and a second deforming portion that connects the second connecting portion and the flat portion. .

A flexible substrate has a main-body part and the protrusion part connected to a flat part.
The protrusion is provided for each of the two adjacent battery modules on at least one side of the main body portion along the adjacent direction of the two adjacent battery modules.

  ADVANTAGE OF THE INVENTION According to this invention, it can suppress that a flexible substrate is cracked by expansion | swelling and shrinkage | contraction of a battery module in a battery pack.

It is a figure which shows an example of the battery pack of embodiment. It is a figure which shows a bus bar and a flexible substrate. It is a figure which shows the other example of a flexible substrate. It is a figure for demonstrating an example of the assembly process of a battery pack. It is a figure for demonstrating an example of the assembly process of a battery pack.

Hereinafter, embodiments will be described in detail with reference to the drawings.
Drawing 1 is a figure showing an example of a battery pack of an embodiment.
The battery pack shown in FIG. 1 includes a plurality of battery modules Bm, and convex bus bars (for example, spring bus bars) Bb that connect terminals of the battery modules Bm so that the battery modules Bm are electrically connected in series. And a flexible substrate FPC connected to the bus bar Bb. The battery pack shown in FIG. 1 includes eight battery modules Bm, but the number of battery modules Bm is not limited to eight.

Each battery module Bm is arranged adjacent to each other.
Moreover, the elastic member E is arrange | positioned between each of each battery module Bm. The elastic member E suppresses a change in the distance between terminals of adjacent battery modules Bm due to expansion and contraction of the battery module Bm. Thereby, since the stress concerning the connection part of flexible board | substrate FPC and bus-bar Bb by expansion | swelling of each battery module Bm can be relieve | moderated, it can suppress that a flexible board | substrate FPC is cracked by the stress. Note that the elastic member E may have a function of releasing heat released from the battery module Bm to the outside. Further, the elastic member E may be omitted.

  Each battery module Bm is sandwiched between a pair of end plates Pt. Each battery module Bm is clamped between a pair of end plates Pt by fastening each battery module Bm between a pair of end plates Pt by bolts Bt and nuts N passing through the four corners of the end plate Pt. The The pair of end plates Pt, bolts Bt, and nuts N are examples of restraining members. Each battery module Bm is constrained between a pair of end plates Pt, so that a restraining load generated in a direction in which the pair of end plates Pt face each other, that is, in an adjacent direction (x direction) of each battery module Bm, Since a load can be applied to each battery module Bm, each battery module Bm can be prevented from being degraded in performance. Moreover, since each battery module Bm is restrained, the expansion of each battery module Bm can be suppressed. Thereby, since the stress concerning the connection part of flexible board | substrate FPC and bus-bar Bb by expansion | swelling of each battery module Bm can be relieve | moderated, it can suppress that a flexible board | substrate FPC is cracked by the stress.

  2A is a diagram showing the bus bar Bb shown in FIG. 1, and FIG. 2B is a diagram for explaining a connection configuration of the battery module Bm, the bus bar Bb, and the flexible substrate FPC.

  The bus bar Bb is connected to the terminal T of one battery module Bm of the two adjacent battery modules Bm and the second connection connected to the terminal T of the other battery module Bm. Part C2, flat part F, first deformed part D1 connecting first connecting part C1 and flat part F, and second deformed part D2 connecting second connecting part C2 and flat part F Have

  The first connection portion C1 is connected to a terminal T of one battery module Bm by a nut N, and the second connection portion C2 is connected to a terminal T of the other battery module Bm by a nut N.

  The 1st deformation | transformation part D1 and the 2nd deformation | transformation part D2 are formed in the direction away from the surface Fa with the terminal T of battery module Bm. Accordingly, when the two adjacent battery modules Bm expand and the terminals T of the two adjacent battery modules Bm are separated from each other, the first connection portion C1 and the second connection portion C2 are separated from each other. The angle θ1 formed by the first connection portion C1 and the first deformation portion D1 and the angle θ2 formed by the first deformation portion D1 and the flat portion F as the first connection portion C1 and the second connection portion C2 are separated from each other. The angle θ3 formed by the flat portion F and the second deformable portion D2 and the angle θ4 formed by the second deformable portion D2 and the second connecting portion C2 are respectively increased, and the surface on which the terminal T of the battery module Bm exists. The height h of the flat portion F with respect to Fa becomes smaller. When the two adjacent battery modules Bm contract and the terminals T of the two adjacent battery modules Bm approach each other, the first connection portion C1 and the second connection portion C2 approach each other. As the first connection portion C1 and the second connection portion C2 approach each other, the angles θ1 to θ4 decrease, and the height h of the flat portion F increases. That is, a part of the stress in the adjacent direction of each battery module Bm applied to the connection portion between the flexible substrate FPC and the flat portion F of the bus bar Bb due to the expansion or contraction of the two adjacent battery modules Bm is expressed by the flat portion F. It can be converted into stress in the height h direction (z direction). As a result, the stress in the adjacent direction of each battery module Bm (stress that cannot be alleviated by the elastic member or the restraining member) applied to the connection portion between the flexible substrate FPC and the flat portion F can be relieved, and the flexible substrate FPC is cracked. Can be further suppressed. Further, since the first deformation portion D1 and the second deformation portion D2 are formed in a direction away from the surface Fa with the terminal T of the battery module Bm, the flexible substrate FPC can be moved away from the battery module Bm. The flexible substrate FPC can be made difficult to receive heat released from the battery module Bm.

  Note that the flexible substrate FPC has high resistance to stress in the height h direction of the flat portion F, and the connection between the flexible substrate FPC and the flat portion F is caused by expansion or contraction of two adjacent battery modules Bm. It is assumed that there is no problem even if the stress in the height h direction of the flat portion F is applied.

FIG. 2C is a diagram showing the flexible substrate FPC shown in FIG.
The flexible substrate FPC has two main body portions Bd, seven projecting portions Pr, seven chip fuses Fs, and seven wirings L. In addition, the one end of the wiring L shall be electrically connected to each terminal T of two battery modules Bm adjacent through the bus bar Bb. Further, a chip fuse Fs is connected in the middle of the wiring L. In addition, the other end of the wiring L is connected to a voltage detection unit (not shown) via a connector or a harness (not shown). The battery monitoring unit monitors the voltage applied to the battery module Bm based on the voltage applied to the wiring L. The chip fuse Fs is cut off by a large current flowing through the battery module Bm, thereby preventing the battery monitoring unit from being damaged by the large current.

  The protruding portion Pr is provided for each of the two adjacent battery modules Bm on one side of the main body portion Bd along the adjacent direction of the two adjacent battery modules Bm. In other words, the protruding portion Pr is provided for each of two adjacent battery modules Bm on one side along the longitudinal direction (x direction) of the main body portion Bd. In other words, the protruding portion Pr overlaps the flat portion F of the bus bar Bb connected to the two adjacent battery modules Bm on one side of the main body Bd along the adjacent direction of the two adjacent battery modules Bm. It is provided so as to protrude in the direction (y direction) from the main body part Bd to the flat part F for each position. Thus, since the projecting portion Pr is provided on the main body portion Bd so as to project from the main body portion Bd, the connection between the main body portion Bd and the projecting portion Pr is used as a fulcrum, so that the two adjacent battery modules Bm It is easy to tilt in the adjacent direction. Therefore, the stress (elastic member) in the adjacent direction of each battery module Bm applied to the connection portion between the flexible substrate FPC and the flat portion F due to the inclination of the protruding portion Pr due to the expansion or contraction of the two adjacent battery modules Bm. And stress that cannot be alleviated by the restraining member or the bus bar Bb), and the occurrence of cracks in the flexible substrate FPC can be further suppressed.

  Further, the protruding portion Pr is directly connected to the flat portion F of the bus bar Bb by a bolt Bt and a nut N penetrating the protruding portion Pr and the flat portion F. Thereby, since the protrusion part Pr and the flat part F can be connected in parallel, the connection strength of the protrusion part Pr and the flat part F can be raised. The bolt may be fixed to the flat portion F by welding, and the projecting portion Pr may be directly connected to the flat portion F of the bus bar Bb by the bolt and the nut.

  Moreover, the protrusion Pr is connected to the surface Fac on the side far from the surface Fa where the terminal T of the battery module Bm is located, on both surfaces of the flat portion F. Thereby, since the flexible substrate FPC can be kept away from the battery module Bm, the flexible substrate FPC can hardly receive the heat released from the battery module Bm.

  The chip fuse Fs is provided at a connection portion (for example, a broken line frame a) between the main body portion Bd and the protruding portion Pr. Thereby, the large current flowing through the battery module Bm can be cut off before flowing through the wiring L (wiring L on the side not connected to the bus bar Bb), the connector, the harness, or the like beyond the chip fuse Fs.

FIG. 3 is a diagram illustrating another example of the flexible substrate FPC.
For example, as illustrated in FIG. 3A, the protruding portion Pr may have a shape that expands as a connecting portion (for example, a broken line frame b) with the main body portion Bd approaches the main body portion Bd. Thereby, it is possible to prevent cracks from being formed in the connection portion between the main body portion Bd and the projecting portion Pr due to expansion and contraction of the battery module Bm.

  Further, for example, as shown in FIG. 3B, a flexible substrate FPC may be configured by one main body Bd. In the case of such a configuration, the protruding portion Pr is provided for each of two adjacent battery modules Bm on both sides of the main body Bd along the adjacent direction of the two adjacent battery modules Bm. In other words, the protrusion Pr is provided on each of the two adjacent battery modules Bm on both sides along the longitudinal direction of the main body Bd. In other words, the protrusion Pr is a flat portion F of the bus bar Bb connected to the two adjacent battery modules Bm on both sides of the main body Bd along the adjacent direction of the two adjacent battery modules Bm. Are provided so as to protrude in a direction from the main body part Bd toward the flat part F at each position overlapping with.

Next, an example of the assembly process of the battery pack of the embodiment will be described.
FIG.4 and FIG.5 is a figure for demonstrating an example of the assembly process of the battery pack of embodiment.

  First, as shown in FIG. 4, battery modules Bm and elastic members E are alternately arranged, end plates Pt are arranged outside the battery modules Bm at both ends, and between the end plates Pt by bolts Bt and nuts N. The battery modules Bm are restrained by tightening.

  Next, as shown in FIG. 5, the terminal T of one battery module Bm out of the two adjacent battery modules Bm passes through the first connection portion C1 of the bus bar Bb and the terminal of the other battery module Bm. After passing the second connection portion C2 of the bus bar Bb through T, the nut N connects the first connection portion C and the terminal T of one battery module Bm, and the second connection portion C2 and the other The terminal T of the battery module Bm is connected.

  Then, as shown in FIG. 2B, the protrusion Pr of the flexible substrate FPC and the flat part F of the bus bar Bb are connected by a bolt Bt and a nut N. In addition, when the protruding portion Pr of the flexible substrate FPC and the flat portion F of the bus bar Bb are connected, the support portion that supports the main body portion Bd so that the main body portion Bd of the flexible substrate FPC does not tilt toward the battery module Bm. You may prepare for a pack. Specifically, the flexible substrate FPC may be provided with a support portion, or the support portion may be provided above the battery module Bm.

  As described above, the battery pack according to the embodiment can relieve the stress applied to the connection portion between the flexible board FPC and the bus bar Bb due to the expansion and contraction of the battery module Bm, thereby suppressing the flexible board FPC from cracking. can do.

The present invention is not limited to the above embodiment, and various improvements and modifications can be made without departing from the scope of the present invention.
For example, the protruding portion Pr and the flat portion F may be directly connected by ultrasonic welding without using the bolt Bt and the nut N, bonding with an adhesive, or the like.

  Further, for example, a part of the front end side of the protruding portion Pr of the flexible substrate FPC may be a bus bar. Specifically, the base portion of the projecting portion Pr is formed by using the base of the projecting portion Pr (portion close to the connection portion between the main body Bd and the projecting portion Pr) as a flexible substrate FPC and the tip of the projecting portion Pr as a metal bus bar. And the tip. Thereby, the protrusion part Pr which protrudes from the main-body part Bd of flexible substrate FPC can be decreased, and it becomes possible to take many flexible substrates which can be manufactured from one large film. In this case, if the bus bar at the front end is a convex shape as shown in the above embodiment, it is not necessary to connect the projecting portion Pr and the flat portion F with the bolt Bt and the nut N in the battery pack assembling process, and the process is simple. become.

Bm Battery module E Elastic member Bb Bus bar FPC Flexible substrate

Claims (5)

A first connection connected to a terminal of one of the two adjacent battery modules and a second connection connected to a terminal of the other of the two adjacent battery modules A convex portion having a first portion, a flat portion, a first deforming portion connecting the first connecting portion and the flat portion, and a second deforming portion connecting the second connecting portion and the flat portion. Bus bar,
A flexible substrate having a main body portion and a protruding portion connected to the flat portion;
With
The protrusion is provided for each of the two adjacent battery modules on at least one side of the main body along the adjacent direction of the two adjacent battery modules. The battery pack according to claim 1,
A battery pack, wherein a chip fuse is provided at a connection portion between the main body portion and the protruding portion. The battery pack according to claim 1,
The first and second deformed portions are formed in a direction away from the surface where the terminals of the battery module are located,
The projecting portion is connected to a surface of the flat portion, which is far from a surface where the terminal of the battery module is located, on both surfaces of the flat portion. The battery pack according to claim 1,
The protruding portion is directly connected to the flat portion. The battery pack according to claim 1,
The projecting portion has a shape that widens as a connection portion with the main body portion approaches the main body portion.

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