JP3184110U - Battery pack and its frame - Google Patents

Abstract

An assembled battery frame for assembling a battery cell having a sheet-like electrode on one side is provided.
A frame body of an assembled battery is installed on a frame plate 120 having an inner side 122 and an outer side 124, and on the inner side of the frame plate, and forms two opposing storage spaces in the frame plate. The cell 200 is placed in the one storage space, and the sheet-like electrode 220 is installed on the outer side of the frame plate, the support plate 140 that can be bent on the outer side, and the sheet-like electrode on the outer side. And a clamping mechanism 160 for fixing the electrode 220.
[Selection] Figure 1

Description

  The present invention relates to an assembled battery and its frame, and more particularly to a large lithium assembled battery and its frame.

  Lithium batteries have advantages such as high energy, high charge / discharge efficiency and long life. Currently, it is widely used in mobile devices and consumer electronics products. In response to market demands in recent years, lithium battery product technology has been greatly upgraded, for example, improved high current discharge capability and safety. In the future, it aims to be applied to large products, and potential markets include batteries for electric vehicles, power tools, and energy storage.

  Usually, the current electric vehicle power system is an assembled battery in which similar battery cells in series or parallel are assembled. The capacity of the assembled battery is related to the travel distance of the electric vehicle. If a battery pack with a large capacity is used, it is possible to make the mileage longer, but the space occupied by the battery pack increases and the weight of the vehicle also increases. On the other hand, there is a problem that the travel distance cannot be secured if a small capacity battery pack is used. Therefore, it is necessary to further increase the amount of energy (electric power that can be provided in unit volume or unit weight) of the assembled battery. If the volume and weight of the battery can be reduced on the premise that the capacity of the assembled battery is not reduced, the amount of energy of the assembled battery can be increased and can be applied to an electric vehicle.

  In addition, in the case of a series lithium assembled battery, the number of battery cells increases, and it is necessary to increase the number of frames and parts for assembling the battery cells, which increases the development cost of the mold. In addition, since the volume of the assembled battery increases, the occupied space also increases and the vehicle body design cannot be made free.

  The present invention has been developed in view of the above-mentioned drawbacks of the prior art, and an object of the present invention is to provide an assembled battery and its frame that increase the energy amount of the assembled battery and reduce the development cost of the mold.

  In view of such a point, one object of the present invention is to design a mold for assembling an arbitrary number of battery cells by a plurality of frames, and for assembling different amounts of battery cells. It is an object of the present invention to provide an assembled battery frame that is not necessary, is easy to manufacture and assemble, and can improve efficiency.

  Another object of the present invention is to maintain a very high space utilization rate and to assemble an arbitrary number of battery cells by a plurality of frames, and to form a mold for assembling different amounts of battery cells. It is an object of the present invention to provide an assembled battery that does not need to be designed, is easy to manufacture and assemble, and can improve efficiency.

  In order to achieve the above object, the frame of the assembled battery of the present invention is used for assembling a battery cell having a sheet-like electrode on one side. The frame includes a frame plate, a support plate, and a clamping mechanism. The frame plate has an inner side and an outer side. The support plate is installed inside the frame plate, forms two opposing storage spaces in the frame plate, the battery cell is placed in the single storage space, and the sheet-like electrode is connected to the frame plate. You can bend to this outside of the board. This clamping mechanism is installed on one side of this outer side, and a sheet-like electrode is fixed to this one side of the outer side.

  In an embodiment of the present invention, the clamping mechanism includes a plurality of screws and is used to lock the sheet-like electrode on the outside of the frame plate. The frame further has a plurality of engagement structures installed on the outside of the frame plate. Specifically, the plurality of engagement structures are a plurality of tenons. The support plate preferably has a hollow.

  In an embodiment of the present invention, the frame plate is provided with a plurality of heat radiating ports, and the plurality of heat radiating ports are provided on the frame plate approaching the clamping mechanism. The frame further has a buffer member, and the buffer member is installed on the support plate and between the battery cell and the support plate.

  In order to achieve the other object, the present invention provides an assembled battery including a plurality of battery cells and a plurality of frames. The plurality of battery cells have each sheet-like electrode on one side in parallel. Each battery cell is installed between both adjacent frames. Each frame includes a frame plate, a support plate, and a clamping mechanism. The frame plate has an inner side and an outer side. The support plate is installed inside the frame plate to form two opposing storage spaces in the frame plate, the battery cell is placed in the single storage space, and the sheet-like electrode is It may be bent on this outside of the frame plate. This clamping mechanism is installed on one side of this outer side, and a sheet-like electrode is fixed to this one side of the outer side.

  In an embodiment of the present invention, adjacent battery cells are electrically connected by bending two sheet-like electrodes to the outside of the same frame plate. For example, the clamping mechanism further includes a plurality of screws and is used to lock the two sheet-like electrodes on the outside of the frame plate. The two sheet-like electrodes are electrically connected by laser welding.

  In the embodiment of the present invention, each frame body further has a plurality of engagement structures installed on the outside of the frame plate, and is used for engaging other adjacent frame bodies. Specifically, the engagement structure is a plurality of tenons. The support plate preferably has a hollow.

  In an embodiment of the present invention, the frame plate is provided with a plurality of heat radiating ports, and the plurality of heat radiating ports are provided on the frame plate approaching the clamping mechanism. The frame body further includes a buffer member, and the buffer member is preferably installed on the support plate and between the battery cell and the support plate.

  According to the frame of the assembled battery provided by the present invention, the purpose of reducing the occupied space of the conventional series or parallel battery cells and increasing the energy amount of the assembled battery can be realized. According to the present invention, it is possible to provide an assembled battery in which an arbitrary number of battery cells can be assembled by a plurality of frames, and it is not necessary to design a mold for assembling different amounts of battery cells. Can do. Also, the manufacture and assembly are convenient and the efficiency can be improved.

  Hereinafter, a specific implementation method of the multilayer via laminated structure according to the present invention will be described in detail with reference to the drawings.

It is a disassembled perspective view of the frame of an assembled battery and the battery cell in one Example of this invention. It is a disassembled perspective view of the assembled battery in one Example of this invention. It is a perspective view of the assembled battery in a present Example.

  FIG. 1 is an exploded perspective view of an assembled battery frame and battery cells according to an embodiment of the present invention. The frame 100 of the present embodiment is used for assembling the battery cell 200. The battery cell 200 is preferably a thin lithium battery. The battery cell 200 has a sheet-like electrode 220 on one side. Specifically, the sheet-like electrode 220 includes a positive electrode 2201 and a negative electrode 2202.

  As shown in FIG. 1, the frame 100 includes a frame plate 120, a support plate 140, a clamping mechanism 160, and a plurality of engagement structures 180. The material of the frame plate 120 is preferably engineering plastic (engineering plastic), and the frame plate 120 includes an inner side 122 and an outer side 124. The support plate 140 is installed on the inner side 122 of the frame plate 120 and forms two opposing storage spaces in the frame plate 120. That is, the support plate 140 bisects the space in the frame plate 120. As shown, the support plate 140 includes a hollow 145. The shape of the hollow 145 is substantially parallel to the frame plate 120 and is used to increase the structural strength of the frame plate 120 and reduce the weight of the frame 100. The present invention does not specifically limit the shape of the hollow 145, and other suitable shapes are within the protection scope of the present invention. In this embodiment, the frame plate 120 and the support plate 140 are integrally formed, and are formed by, for example, mold molding, injection molding, or the like.

  The frame body 100 further includes a plurality of engagement structures 180 installed on the outer side 124 of the frame plate 120. Specifically, the engagement structure 180 is a plurality of tenons. The plurality of mortises are provided with tenons 182 and mortise holes 184 that are alternately arranged, and are used to engage another frame body 100 (see FIG. 3 for details).

  The battery cell 200 is placed on the support plate 140, that is, in the one storage space, and the sheet electrode 220 can be bent to the outer side 124 of the frame plate 120. As shown in FIG. 1, in the embodiment of the present invention, the battery cell 200 is placed in the storage space on the back side of the support plate 140, and the positive electrode 2201 is bent to the outside 124 of the frame plate 120. Further, the battery cell 200 may be placed in a storage space on the front side of the support plate 140.

  The frame body 100 further includes a buffer member 190. The buffer member 190 is installed in front of the support plate 140 and between the battery cell 200 and the support plate 140. The buffer member 190 is used to fix the battery cell 200 and prevent impact and vibration on the battery cell 200 from the outside, and enhance the reliability of the battery.

  The clamping mechanism 160 is installed on one side of the outer side 124 and is used to fix the sheet-like electrode 220 on one side of the outer side 124. In this embodiment, the one side is the upper side of the frame plate 120. However, the present invention is not limited to the upper side. The clamping mechanism 160 may be installed with respect to the sheet-like electrode 220. In this embodiment, the clamping mechanism 160 includes a plurality of screws 162 and is used to lock the sheet-like electrode 220 to the outer side 124 of the frame plate 120. Specifically, the sheet-like electrode 220 has a hole for the screw 162. The screw 162 can penetrate the sheet-like electrode 220. A nut or a clamping plate (not shown) is used to clamp and fix the sheet-like electrode 220 to one side of the frame plate 120 with respect to the screw 162.

  Considering the heat dissipation of the battery, the heat dissipation amount increases as it gets closer to the electrode. Therefore, a plurality of heat radiation ports 126 are installed in the frame plate 120. In addition, the heat radiation port 126 is installed in the frame plate 120 approaching the clamping mechanism 160.

  Hereinafter, the assembled battery using the frame 100 in the present embodiment will be described in detail, and the advantages of the frame 100 in the present embodiment will be described.

  Please refer to FIG. 2 and FIG. FIG. 2 is an exploded perspective view of an assembled battery according to an embodiment of the present invention. FIG. 3 is a perspective view of the assembled battery in the present embodiment. In FIG. 3, no battery cell is displayed.

  In the present embodiment, the assembled battery 300 includes a plurality of battery cells 200 and a plurality of frames 100. The plurality of battery cells 200 have each sheet-like electrode on one side in parallel. Specifically, the sheet-like electrode 220 includes a positive electrode 2201 and a negative electrode 2202. As shown in FIG. 2, each battery cell 200 is installed between both adjacent frames 100.

  In the above embodiment, the frame body 100 includes the frame plate 120, the support plate 140, the clamping mechanism 160, and a plurality of engagement structures 180. The frame plate 120 includes an inner side 122 and an outer side 124. The support plate 140 is installed on the inner side 122 of the frame plate 120 to form two opposing storage spaces in the frame plate 120. The support plate 140 includes a hollow 145.

  In this embodiment, the battery cell 200 is placed on the support plate 140, that is, in the one storage space, and the sheet-like electrode 220 can be bent to the outer side 124 of the frame plate 120. Specifically, two adjacent battery cells 200 are electrically connected by bending two sheet-like electrodes 220 to the outside 124 of the same frame plate 120. As shown in FIG. 3, the positive electrode 2201 and the negative electrode 2202 of the adjacent battery cells 200 are connected in series by bending the outer side 124 of the same frame plate 120. In addition, by bending the positive electrode 2201 and the negative electrode 2202 of the battery cell 200, they can be connected in series or in parallel according to demand.

  In this embodiment, the clamping mechanism 160 includes a plurality of screws 162 and is used to lock the sheet-like electrode 220 to the outer side 124 of the frame plate 120. Further, the two sheet-like electrodes 220 are more stably electrically connected by laser welding, thereby reducing the contact resistance between the sheet-like electrodes 220 and reducing the heat radiation amount. Considering the heat dissipation of the battery, the heat dissipation amount increases as it gets closer to the electrode. Accordingly, the frame plate 120 is provided with a plurality of heat radiation ports 126. In addition, the heat radiation port 126 is installed in the frame plate 120 approaching the clamping mechanism 160.

  As shown in FIG. 3, the engagement structure 180 is installed on the outer side 124 of the frame plate 120 and is used for engaging another frame body. Specifically, the engagement structure 180 is a plurality of tenons. The plurality of mortises include tenons 182 and mortises 184 that are alternately arranged, and are used to engage the tenons 182 and mortises 184 of the other frame 100. Further, there is an advantage that it is stably engaged and no other tools are required.

  The frame body 100 further includes a buffer member 190. The buffer member 190 is installed on the support plate 140 and between the battery cell 200 and the support plate 140. The buffer member 190 is used to fix the periphery of the battery cell 200 and prevent impact and vibration on the battery cell 200 from the outside, and enhance the reliability of the assembled battery 300.

  As described above, the frame 100 of the present invention can realize the purpose of reducing the occupied space of the conventional series or parallel battery cells 200 and increasing the energy amount of the assembled battery 300. In addition, with the assembled battery 300 of the present invention, an arbitrary number of battery cells 200 can be assembled using a plurality of frames, and it is not necessary to design a mold for assembling different amounts of battery cells 200. Manufacture and assembly are convenient and efficiency can be improved.

  As described above, the present invention has been described above in the preferred embodiment. However, this is not to limit the present invention. Since various changes and changes are possible without departing from the concept and scope of the present invention, the scope of protection of the present invention is based on the scope determined in the claims for utility model registration below.

DESCRIPTION OF SYMBOLS 100 Frame 120 Frame plate 122 Inner 124 Outer 126 Radiation opening 140 Support plate 145 Hollow 160 Holding mechanism 162 Screw 180 Engagement structure 182 Tenon 184 Tenon 190 Buffer member 200 Battery cell 220 Sheet electrode 2201 Positive electrode 2202 Negative electrode 300 Battery pack

Claims (18)

A battery assembly frame for assembling a battery cell having a sheet-like electrode on one side,
Including a frame plate, a support plate, and a clamping mechanism,
The frame plate includes an inner side and an outer side,
The support plate is installed inside the frame plate, forms two opposing storage spaces in the frame plate, the battery cell is placed in the one storage space, and the sheet-like electrode is in the frame Provided to bend to the outside of the plate,
The clamping mechanism is installed on one side of the outer side, and is used to fix the sheet-like electrode on the one side of the outer side.
An assembled battery frame characterized by the above.   2. The assembled battery frame according to claim 1, wherein the clamping mechanism includes a plurality of screws and is used to lock the sheet-like electrode on the outside of the frame plate.   2. The assembled battery frame according to claim 1, wherein the frame further includes a plurality of engagement structures installed on the outside of the frame plate.   The assembled battery frame according to claim 3, wherein the engagement structure is a plurality of tenons.   The frame of the assembled battery according to claim 1, wherein the support plate has a hollow.   The frame of claim 1, wherein the frame plate is provided with a plurality of heat radiation ports.   The frame body of the assembled battery according to claim 6, wherein the plurality of heat radiation ports are installed on the frame plate approaching the clamping mechanism.   The assembled frame according to claim 1, wherein the frame further includes a buffer member, and the buffer member is provided on a support plate and is disposed between the battery cell and the support plate. . An assembled battery,
In parallel, a plurality of battery cells each having a sheet-like electrode on one side;
Each battery cell includes a plurality of frames installed between two adjacent frames, and each frame includes:
A frame plate with an inner side and an outer side;
Installed inside the frame plate to form two opposing storage spaces in the frame plate, each battery cell being placed in a storage space between the two adjacent frames, and the sheet-like An electrode extends from between the two adjacent frames and bends outwardly; and
A battery assembly comprising: a clamping mechanism that is installed on one side of the outer side and fixes a sheet-like electrode on the one side of the outer side.   The battery cell according to claim 9, wherein the battery cells adjacent to each other are electrically connected by bending two sheet-like electrodes to the outside of the same frame plate.   The assembled battery according to claim 10, wherein the clamping mechanism further includes a plurality of screws and is used to lock the two sheet-like electrodes on the outer side of the frame plate.   The assembled battery according to claim 10, wherein the two sheet-like electrodes are electrically connected by laser welding.   The said each frame body has a some engagement structure further installed in the said outer side of the said frame board, and is used for engaging another adjacent frame body. Assembled battery.   The assembled battery according to claim 13, wherein the engagement structure is a plurality of tenons.   The assembled battery according to claim 9, wherein each of the support plates has a hollow.   The assembled battery according to claim 9, wherein each frame plate is provided with a plurality of heat radiation ports.   The assembled battery according to claim 16, wherein the plurality of heat radiation ports are installed in the frame plate approaching the clamping mechanism.   2. The assembled battery according to claim 1, wherein each of the frames further includes a buffer member, and the buffer member is provided on a support plate and installed between the battery cell and the support plate.