CN220895674U - Auxiliary mounting structure of battery module and energy storage device - Google Patents

Abstract

The auxiliary battery module mounting structure comprises an ascending plate and a descending plate, wherein the ascending plate is transversely arranged at the mounting opening and forms an acute angle with the bottom wall of the energy storage box, and the battery module is stressed to move upwards along the ascending plate; the descending plate is transversely arranged at the installation opening and is positioned on the installation direction of the battery module relative to the ascending plate, and comprises a gentle plate and a descending plate, wherein the gentle plate is flush with the highest part of the ascending plate, the gentle plate and the descending plate form an obtuse angle relation, and the battery module continuously bears force to slide through the gentle plate and then slides into the energy storage box body along the descending plate. The auxiliary mounting structure of the battery module and the energy storage device provided by the utility model enable the battery module to be mounted in a labor-saving and quick manner, and have the advantages of high mounting efficiency and stable and smooth mounting.

Description

Auxiliary mounting structure of battery module and energy storage device

Technical Field

The utility model relates to the technical field of battery module installation, in particular to an auxiliary battery module installation structure and an energy storage device.

Background

In the existing energy storage device, the assembled battery module is required to be installed in the energy storage box, and because the internal space of the energy storage box is relatively narrow and the assembled battery module has very large weight, only two operators can lift the battery module into the energy storage box together, and the upper cover is connected with the energy storage box when the battery module is installed in place, so that the battery module is installed in the energy storage box from top to bottom; therefore, the battery module after the existing energy storage device is installed and assembled is difficult and laborious in the installation process due to the fact that the internal space of the energy storage box is narrow and the battery module is heavy, so that a lot of time can be consumed, the installation efficiency is low, the installation effect is poor, and the assembly requirement of the energy storage device cannot be met.

Disclosure of utility model

In order to overcome the defects of the prior art, the utility model aims to provide an auxiliary mounting structure of a battery module and an energy storage device.

In order to solve the problems, the technical scheme adopted by the utility model is as follows:

The auxiliary mounting structure of the battery module is detachably mounted at a mounting opening of an energy storage box body and is used for mounting the battery module into the energy storage box body, and comprises a rising plate, the auxiliary mounting structure of the battery module is transversely arranged at the mounting opening and forms an acute angle relation with the bottom wall of the energy storage box body, and the battery module is stressed to move upwards along the rising plate; and the descending plate is transversely arranged at the mounting opening and is positioned on the mounting direction of the battery module relative to the ascending plate, and comprises a gentle plate and a descending plate, wherein the gentle plate is flush with the highest part of the ascending plate, the gentle plate and the descending plate form an obtuse angle relation, and the battery module continuously slides through the gentle plate under force and then slides into the energy storage box body along the descending plate.

Further, the auxiliary mounting structure of the battery module further comprises a positioning separation block, one end of the positioning separation block is connected with the descending plate, and the other end of the positioning separation block extends towards the inside of the energy storage box body along the mounting direction of the battery module.

Further, the gentle plate is arranged in parallel with the bottom wall of the energy storage box body.

Further, the ascending plate and the descending plate are integrally formed.

Further, the ascending plate member comprises an ascending plate and a first supporting plate, the ascending plate and the supporting plate form an acute included angle relation, the descending plate member further comprises a second supporting plate, and the first supporting plate is parallel to the second supporting plate and perpendicular to the bottom wall of the energy storage box body.

Further, the ascending plate and the bottom wall of the energy storage box body form an acute angle relation of θ1=10-30 degrees.

Further, the gentle plate and the descending plate form an obtuse angle relation of θ2=150° -170 °.

An energy storage device comprises a battery module; the battery module auxiliary mounting structure is used for mounting the battery module into the energy storage box body; and the two ends of the fixed connecting piece are respectively connected with the inner walls of the energy storage box body, which are positioned on the two sides of the battery module in the installation direction, and the fixed connecting piece is tightly attached to the battery module.

Compared with the prior art, the utility model has the beneficial effects that:

The auxiliary mounting structure of the battery module is firstly mounted at the mounting opening of the energy storage box body, specifically, the ascending plate and the descending plate of the auxiliary mounting structure of the battery module are both transversely arranged at the mounting opening, and compared with the ascending plate, the descending plate is more inward, the battery module is placed right in front of the ascending plate, the battery module is pushed to move up to the gentle plate of the descending plate along the upper surface of the ascending plate forming an acute angle with the bottom wall of the energy storage box body (the ascending plate plays a first guiding role for the movement of the battery module), after the battery module is continuously pushed to slide through the gentle plate, the descending plate forms an obtuse angle with the bottom wall of the energy storage box body and then slides down into the energy storage box body (the descending plate plays a second guiding role for the movement of the battery module), at the moment, the battery module is continuously pushed until the battery module is mounted in place in the energy storage box body, an operator is not required to lift the battery module for mounting, the auxiliary mounting structure of the battery module is labor-saving and fast, the mounting efficiency is high, the battery module is stably mounted, and the battery module is required to be taken down (such as maintenance) and the battery module is required to slide down along the opposite to the bottom wall of the energy storage box body, and the battery module is required to slide smoothly and only to slide down.

Additional features and advantages of the utility model will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model. The objectives and other advantages of the utility model may be realized and attained by the structure and/or process particularly pointed out in the written description and claims hereof as well as the appended drawings.

Drawings

Fig. 1 is a schematic structural view of an auxiliary mounting structure of a battery module mounted on an energy storage box according to an embodiment of the present utility model;

fig. 2 is a schematic structural diagram of an energy storage case, a battery module auxiliary mounting structure, and a battery module according to an embodiment of the present utility model;

FIG. 3 is an enlarged view at A of FIG. 2;

Fig. 4 is a schematic view illustrating a structure in which a battery module is mounted in an energy storage case according to an embodiment of the present utility model;

Fig. 5 is a schematic structural diagram of an energy storage device according to an embodiment of the present utility model (after hiding a side cover);

Reference numerals illustrate:

10-auxiliary mounting structure of battery module;

11-lifting plate, 111-lifting plate, 112-first supporting plate;

12-descending plate, 121-gentle plate, 122-descending plate, 123-second supporting plate;

13-positioning a separation block;

20-an energy storage box body, 20 a-a mounting opening, 21-side walls and 22-a bottom wall;

30-battery modules and 31-battery units;

40-fixing the connecting piece and 41-connecting the bending part;

1-an energy storage device;

Detailed Description

The following will describe embodiments of the present utility model in detail with reference to the drawings and examples, thereby solving the technical problems by applying technical means to the present utility model, and realizing the technical effects can be fully understood and implemented accordingly. It should be noted that these specific descriptions are only for easy and clear understanding of the present utility model by those skilled in the art, and are not meant to be limiting; for example, the first and second embodiments of the present utility model are not limited thereto, but are merely for describing serial numbers of a plurality of identical or similar devices and mechanisms, and those skilled in the art may readjust the serial numbers for convenience of description or in the technical scheme arranging process; and various embodiments have been described with alternatives to some of the mechanisms, and these alternatives may be applied to other identical or similar devices, mechanisms; and as long as no conflict is formed, each embodiment of the present utility model and each feature of each embodiment may be combined with each other, and the formed technical solutions are all within the protection scope of the present utility model.

The following describes the technical scheme of the utility model in detail through the attached drawings and specific embodiments:

Examples

Referring to fig. 1 to 5, the present embodiment provides a battery module auxiliary mounting structure 10, the battery module auxiliary mounting structure 10 being detachably mounted at a mounting opening 20a of an energy storage case 20, the mounting opening 20a being a side opening formed when one side cover of the energy storage case 20 is not mounted, the battery module auxiliary mounting structure 10 being for smoothly mounting a battery module 30 into the energy storage case 20 from the mounting opening 20a, the battery module 30 generally including at least two battery cells 31 having a large weight, the battery module auxiliary mounting structure 10 including a rising plate 11 and a falling plate 12, and further including a positioning dividing block 13, specifically:

The lifting plate 11 is transversely arranged at the mounting opening 20a, and the lifting plate 11 and the bottom wall 22 of the energy storage box 20 form an acute included angle, that is, the lifting plate 11 and the bottom wall 22 form a gentle lifting channel, the battery module 30 can easily move upwards along the lifting plate 11 under the stress, and at the moment, the lifting plate 11 plays a first guiding role on the movement of the battery module 30.

Preferably, the lifting plate 11 and the bottom wall 22 of the energy storage box 20 form an acute angle relationship of θ1=10° -30 °, and the lifting plate 11 and the bottom wall 22 form a gentle lifting channel, so that the battery module 30 moves upwards more easily.

The descending plate 12 is transversely arranged at the mounting opening 20a and is located in the mounting direction of the battery module 30 relative to the ascending plate 11, the descending plate 12 comprises a gentle plate 121 and a descending plate 122, the gentle plate 121 is flush with the highest position of the ascending plate 11, so that the descending plate 12 is well connected with the ascending plate 11, the gentle plate 121 and the descending plate 122 form an obtuse angle relation, that is, the descending plate 122 and the gentle plate 121 form a gentle descending channel, the battery module 30 continuously slides down into the energy storage box 20 after being stressed by the gentle plate 121, and at the moment, the descending plate 12 plays a second guiding role on the movement of the battery module 30.

Preferably, the flat plate 121 and the descending plate 122 form an obtuse angle relationship of θ2=150° -170 °, and the obtuse angle is set such that the descending plate 122 and the flat plate 121 form a gentle descending channel, so that the battery module 30 descends more smoothly.

One end of the positioning separation block 13 is connected with the descending plate 122, the other end extends towards the inside of the energy storage box 20 along the installation direction (arrow direction in fig. 2) of the battery module 30, the positioning separation block 13 is matched with the battery units 31, the number of the positioning separation blocks is equal to the number of the battery units 31 minus 1, a spacing groove is formed between every two adjacent battery units 31, and the positioning separation block 13 is inserted into the spacing groove to guide the installation of the battery module 30, namely, the positioning separation block 13 plays a third guiding role on the installation of the battery module 30.

The auxiliary mounting structure 10 for the battery module has progressive three guiding functions when the battery module 30 is mounted in the energy storage box 20 from the mounting opening 20a, so that the battery module 30 is stable and smooth to mount, saves labor, is rapid and has high mounting efficiency.

In this embodiment, preferably, the flat plate 121 is disposed parallel to the bottom wall 22 of the energy storage box 20, and the width of the flat plate 121 is generally 15mm, so that the battery module 30 moves horizontally on the flat plate 121, which is relatively labor-saving, and plays a role in transitional engagement between the rising plate 11 and the falling plate 122.

In this embodiment, preferably, the lifting plate 11 includes a lifting plate 111 and a first support plate 112, the lifting plate 111 and the first support plate 112 form an acute angle, and the descending plate 12 further includes a second support plate 123, where the first support plate 112 is parallel to the second support plate 123 and perpendicular to the bottom wall 22 of the energy storage box 20; as described above, the separate arrangement of the ascending plate 11 and the descending plate 12 is convenient for the integrated formation of the descending plate 12 and the bottom wall 22, and the ascending plate 11 is in a detachable structure, the connection between the ascending plate 11 and the descending plate 12 can be realized by the mutual abutting of the first support plate 112 and the second support plate 123, the ascending plate 11 is not required to be fixed by adopting a screw in addition, the ascending plate 11 is directly taken down after the installation of the battery module 30, the ascending plate 11 can be repeatedly used, and when the battery module 30 needs to be detached, the operation is very convenient by only pushing the battery module 30 to slide across the descending plate 12 in the opposite direction.

In a modification, the ascending plate 11 and the descending plate 12 are integrally formed, so that the processing cost can be reduced, and the use is more convenient.

Referring to fig. 5, the present embodiment further provides an energy storage device 1, where the energy storage device 1 includes a battery module 30, an energy storage box 20 and a fixing connection member 40, the above-mentioned auxiliary battery module mounting structure 10 is horizontally detachably mounted at the mounting opening 20a of the energy storage box 20, and the auxiliary battery module mounting structure 10 is located on the bottom wall 22 of the energy storage box 20, and the auxiliary battery module mounting structure 10 is used for smoothly mounting the battery module 30 into the energy storage box 20.

The both ends of fixed connection spare 40 all bend and set up into the connection department of bending 41, and the connection department of bending 41 at both ends is connected respectively and is located the inside wall 21 of the both sides on the installation direction of battery module 30 on the energy storage box 20, accessible screw connection, and the middle pole main part of fixed connection spare 40 hugs closely battery module 30 one side, and the battery module 30 of installing in the energy storage box 20 can be fixed to the setting of fixed connection spare 40, further guarantees that battery module 30 installs in place, avoids battery module 30 to produce and rocks and lead to battery unit 31 to damage.

In this embodiment, the above-mentioned auxiliary mounting structure 10 for battery module is firstly mounted at the mounting opening 20a of the energy storage box 20, specifically, the ascending plate 11 and the descending plate 12 of the auxiliary mounting structure 10 for battery module are both laterally disposed at the mounting opening 20a, and the descending plate 12 is further inward than the ascending plate 11, the battery module 30 is placed right in front of the ascending plate 11, the battery module 30 is pushed to move up to the flat plate 121 (first guiding mounting) of the descending plate 12 along the upper surface of the ascending plate 11 forming an acute angle with the bottom wall 22 of the energy storage box 20, after the battery module 30 is continuously pushed to slide over the flat plate 121, the battery module is then slid down into the energy storage box 20 along the descending plate 122 forming an obtuse angle with the bottom wall 22 of the energy storage box 20 (second guiding mounting), the positioning separation block 13 is inserted into the space groove formed between two adjacent battery cells 31 (third guiding mounting), at this time, the battery module 30 is continuously pushed until the battery module 30 is positioned in the energy storage box 20, the battery module 30 is stably mounted in the energy storage box 20 by the screw connection fixing connection connecting member 40, the battery module 30 is not required to be mounted in the energy storage box 20, the auxiliary mounting structure is carried out, the battery module can be mounted in the energy storage box 20 smoothly, and the auxiliary mounting structure is carried out by the battery module is carried out after the battery module is mounted in the energy storage box 20, and the auxiliary mounting structure is completed, the energy storage module is mounted in a high-efficient manner, and the auxiliary mounting structure is carried out, and the battery module mounting of the battery module is carried out smoothly, and the battery module mounting can be mounted in the energy storage device is mounted in the energy storage box 20.

In the case of removing (e.g., repairing) the battery module 30, the battery module 30 is pushed in the opposite direction to slide over the descending plate 12 and then slide over the ascending plate 11, so that the battery module 30 is removed smoothly and with little effort.

Finally, it should be noted that the above description is only a preferred embodiment of the present utility model, and is not intended to limit the present utility model in any way. Any person skilled in the art can make many possible variations and simple substitutions to the technical solution of the present utility model by using the methods and technical matters disclosed above without departing from the scope of the technical solution of the present utility model, and these all fall into the scope of protection of the technical solution of the present utility model.

Claims (8)

1. The utility model provides a supplementary mounting structure of battery module, detachably installs in the installation opening part of energy storage box, is used for with the battery module is installed in the energy storage box, its characterized in that: the auxiliary mounting structure of the battery module comprises

The ascending plate is transversely arranged at the mounting opening and forms an acute angle relation with the bottom wall of the energy storage box body, and the battery module is stressed to move upwards along the ascending plate; and

The descending plate is transversely arranged at the mounting opening and opposite to the ascending plate and positioned on the mounting direction of the battery module, and comprises a gentle plate and a descending plate, wherein the gentle plate is flush with the highest position of the ascending plate, the gentle plate and the descending plate form an obtuse angle relation, and the battery module continues to bear force to slide through the gentle plate and then slide down into the energy storage box along the descending plate.

2. The battery module auxiliary mounting structure according to claim 1, wherein: the auxiliary mounting structure of the battery module further comprises a positioning separation block, one end of the positioning separation block is connected with the descending plate, and the other end of the positioning separation block extends towards the inside of the energy storage box body along the mounting direction of the battery module.

3. The battery module auxiliary mounting structure according to claim 2, wherein: the gentle plate is arranged in parallel with the bottom wall of the energy storage box body.

4. The battery module auxiliary mounting structure according to claim 3, wherein: the ascending plate and the descending plate are integrally formed.

5. The battery module auxiliary mounting structure according to claim 3, wherein: the lifting plate piece comprises a lifting plate and a first supporting plate, wherein the lifting plate and the first supporting plate form an acute included angle relation, the descending plate piece further comprises a second supporting plate, and the first supporting plate is parallel to the second supporting plate and perpendicular to the bottom wall of the energy storage box body.

6. The battery module auxiliary mounting structure according to any one of claims 1 to 5, wherein: the rising plate and the bottom wall of the energy storage box body form an acute angle relation of θ1=10-30 degrees.

7. The battery module auxiliary mounting structure according to claim 6, wherein: the gentle plate and the descending plate form an obtuse angle relation of θ2=150-170 degrees.

8. An energy storage device, characterized in that: comprising

A battery module; and

The battery module auxiliary mounting structure according to any one of claims 1 to 7 is transversely and detachably mounted at a mounting opening of the energy storage box body, and the battery module auxiliary mounting structure is used for mounting the battery module into the energy storage box body;

And the two ends of the fixed connecting piece are respectively connected with the inner walls of the energy storage box body, which are positioned on the two sides of the battery module in the installation direction, and the fixed connecting piece is tightly attached to the battery module.