CN220474768U - Energy storage power station battery package buffer structure - Google Patents

Abstract

The utility model provides a battery pack buffer structure of an energy storage power station, which can reduce damage to the outer surface of a storage battery in the placing process, thereby avoiding the occurrence of conditions such as electric leakage and the like and being beneficial to reducing potential safety hazards. The application comprises the following steps: a housing, a cushioning assembly, and a placement plate; the utility model discloses a buffer assembly, including casing, buffer assembly, spring, buffer assembly, spring, the last chamber of placing that is provided with of casing, buffer assembly installs place the board place on the buffer assembly, include buffer housing, first buffer post, second buffer post, spring and backup pad in the buffer assembly, the backup pad with first buffer post second buffer post and spring coupling, place the board with the backup pad is connected, be provided with on the buffer housing and hold the chamber, the spring first buffer post and second buffer post is installed hold in the chamber.

Description

Energy storage power station battery package buffer structure

Technical Field

The utility model mainly relates to the field of energy storage power stations, in particular to a battery pack buffer structure of an energy storage power station.

Background

Along with the rapid development of the current electric automobile industry, the battery industry is also rapidly developed, and the battery is used as a power source of the electric automobile, so that the energy storage and the capacity of the battery are continuously increased at the present stage, the electric automobile needs to be charged after being used for a period of time, and at the present stage, the electric automobile needs to be charged by using a special charging pile, and the electric energy of the charging pile mainly comes from an energy storage station; the inside a large amount of reserve batteries that have of energy storage station, the inside reserve batteries of energy storage station are put together, and because reserve batteries's capacity and volume are great, when placing the rack in the energy storage station with the reserve batteries, because reserve batteries is harder with the contact surface of rack, in the reserve batteries placing the in-process, probably can lead to the fact the damage to the surface of reserve batteries to produce circumstances such as electric leakage, there is certain potential safety hazard.

Disclosure of Invention

In order to solve the defects in the prior art, the utility model provides the battery pack buffer structure of the energy storage power station, which can reduce the damage to the outer surface of the reserve battery in the placing process, thereby avoiding the occurrence of conditions such as electric leakage and the like and being beneficial to reducing potential safety hazards.

The utility model aims to achieve the aim, and the aim is achieved by the following technical scheme: an energy storage power station battery pack buffering structure, comprising: a housing, a cushioning assembly, and a placement plate; the shell is provided with a placing cavity, the buffer assembly is installed in the placing cavity, the placing plate is placed on the buffer assembly, the buffer assembly comprises a buffer shell, a first buffer column, a second buffer column, a spring and a support plate, the support plate is connected with the first buffer column, the second buffer column and the spring, the placing plate is connected with the support plate, the buffer shell is provided with a containing cavity, and the spring, the first buffer column and the second buffer column are installed in the containing cavity; the placing plate is used for placing a reserve battery, and the first buffer column, the second buffer column and the spring are used for buffering the weight applied to the supporting plate.

According to the buffer structure between the energy storage power station batteries, further, the soft sponge is placed on the upper surface of the placement plate, the anti-skid stripes are arranged on the soft sponge, and the soft sponge is detachably connected with the placement plate.

According to the buffer structure between the energy storage power station batteries, one end of the placing cavity arranged on the shell is in an opening shape, and the other end of the placing cavity is in a closed shape.

According to the buffer structure between the energy storage power station batteries, a plurality of buffer assemblies are arranged in the placing cavity, and the supporting plate is detachably connected with the placing plate.

According to the buffer structure between the energy storage power station batteries, the accommodating cavity is further provided with the first sliding groove and the second sliding groove, one end of the first buffer column is connected with the bottom of the supporting plate, the other end of the first buffer column is movably arranged in the first sliding groove, one end of the second buffer column is connected with the bottom of the supporting plate, and the other end of the second buffer column is movably arranged in the second sliding groove.

According to the buffer structure between the energy storage power station batteries, further, the connection mode of the first sliding groove and the first buffer column and the connection mode of the second sliding groove and the second buffer column are in clearance fit.

According to the buffer structure between the energy storage power station cells, further, the cross section area of the placing cavity is larger than that of the supporting plate.

According to the buffer structure between the energy storage power station batteries, one end of the spring is connected with the bottom of the supporting plate, and the other end of the spring is arranged at the bottom of the accommodating cavity.

According to the buffer structure between the energy storage power station batteries, the enclosing plates are arranged on the placing plates, the enclosing plates are arranged on two sides and one end of the placing plates, and the other end of the placing plates is in an opening shape.

According to the buffer structure between the energy storage power station batteries, the height of the coaming is set to be a preset value, and the coaming and the placing plate are integrally formed.

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

through being provided with casing, buffer unit spare and placing the board, wherein, be provided with on the casing and place the chamber, buffer unit spare installs in placing the chamber, places the board and places on buffer unit spare, contains buffer housing, first buffer post, second buffer post, spring and backup pad in the buffer unit spare, backup pad and first buffer post, second buffer post and spring coupling place the board and be connected with the backup pad, are provided with on the buffer housing and hold the chamber, and spring, first buffer post and second buffer post are installed in holding the chamber.

According to the storage battery placing device, the storage battery placing plate is used for placing the storage battery, the storage battery is placed on the supporting plate, when the storage battery is placed on the placing plate, gravity acting on the placing plate is applied to the supporting plate, and the gravity applied to the supporting plate can be buffered under the action of the first buffer column, the second buffer column and the spring, so that the storage battery can be lowered at a relatively gentle speed in the placing process, the direct contact with the surface of the placing frame and the damage to the outer surface of the storage battery in the placing process are effectively avoided, the occurrence of conditions such as electric leakage is avoided, and potential safety hazards are reduced.

Drawings

FIG. 1 is a schematic illustration of the overall structure of the present utility model;

FIG. 2 is another schematic illustration of the overall structure of the present utility model;

FIG. 3 is a schematic view of the utility model with the placement plate separated from the cushioning assembly;

FIG. 4 is a schematic view of the utility model with a reserve battery placed on the placement plate;

FIG. 5 is a schematic view of the structure of a cushioning assembly of the present utility model;

FIG. 6 is a schematic view of an exploded view of a cushioning assembly in accordance with the present utility model;

the reference numbers shown in the drawings: 1. a housing; 11. a placement cavity; 2. a buffer assembly; 21. a support plate; 22. a first buffer column; 23. a second buffer column; 24. a receiving chamber; 25. a spring; 26. a buffer housing; 3. placing a plate; 4. and (5) storing the battery.

Detailed Description

The utility model will be further described with reference to the accompanying drawings and specific embodiments. It is to be understood that these examples are illustrative of the present utility model and are not intended to limit the scope of the present utility model. Further, it will be understood that various changes or modifications may be made by those skilled in the art after reading the teachings of the utility model, and such equivalents are intended to fall within the scope of the utility model as defined herein.

As shown in fig. 1 to 6, the buffering structure of a battery pack of an energy storage power station according to the present utility model includes: a housing 1, a cushioning assembly 2, and a placement plate 3; the housing 1 is provided with a placing cavity 11, the buffer assembly 2 is installed in the placing cavity 11, the placing plate 3 is placed on the buffer assembly 2, the buffer assembly 2 comprises a buffer shell 26, a first buffer column 22, a second buffer column 23, a spring 25 and a support plate 21, the support plate 21 is connected with the first buffer column 22, the second buffer column 23 and the spring 25, the placing plate 3 is connected with the support plate 21, the buffer shell 26 is provided with a containing cavity 24, and the spring 25, the first buffer column 22 and the second buffer column 23 are installed in the containing cavity 24; the placement plate 3 is used for placing a reserve battery 4, and the first buffer column 22, the second buffer column 23, and the spring 25 are used for buffering the weight applied to the support plate 21.

In order to reduce the damage to the outer surface of the reserve battery 4 in the placing process and avoid the occurrence of electricity leakage and other conditions, the application provides a battery pack buffer structure of an energy storage power station, which can avoid the direct contact with the surface of a placing rack and the damage to the outer surface of the reserve battery 4 in the placing process, thereby avoiding the occurrence of electricity leakage and other conditions, and being beneficial to reducing potential safety hazards, more particularly, the battery pack buffer structure mainly comprises a buffer component 2, a shell 1 and a placing plate 3, a placing cavity 11 is arranged on the shell 1, the buffer component 2 is placed in the placing cavity 11, the buffer component 2 is connected with the placing plate 3, in practical application, when the storage battery is placed on the placing plate 3, the placing plate 3 is connected with the buffer component 2, so that the gravity acting on the placing plate 3 can be transferred to the buffer component 2, the buffer assembly 2 performs buffer treatment, more specifically, the buffer assembly 2 includes a buffer housing 26, a first buffer column 22, a second buffer column 23, a spring 25 and a support plate 21, wherein a receiving cavity 24 with a preset depth is arranged on the buffer housing 26, the receiving cavity 24 does not penetrate through the buffer housing 26, the first buffer column 22, the second buffer column 23 and the spring 25 are installed in the receiving cavity 24, when the gravity acting on the placing plate 3 is transferred to the support plate 21, the support plate 21 is pressed downwards by the gravity, so that the first buffer column 22, the second buffer column 23 and the spring 25 are pressed downwards, and the first buffer column 22, the second buffer column 23 and the spring 25 have a certain buffer force, so that the reserve battery 4 placed on the placing plate 3 can slowly descend, playing a certain buffering role.

Optionally, a soft sponge is placed on the upper surface of the placement plate 3, anti-slip stripes are arranged on the soft sponge, and the soft sponge is detachably connected with the placement plate 3.

In this application embodiment, in order to be able to further reduce the damage that reserve battery 4 caused to reserve battery 4 surface in the course of placing, have placed the software sponge promptly on placing board 3, through having placed the software sponge, can play certain cushioning effect to reserve battery 4, and be provided with anti-skidding stripe on the software sponge, can prevent that reserve battery 4 from placing board 3 from landing, the software sponge can be mainly through the double faced adhesive tape adhesion with the connected mode of placing board 3, also can be through other modes connection, in this application, do not make the concrete limit to the connected mode of software sponge and placing board 3, wherein, it is to be noted that other have cushioning effect article except can be placed on placing board 3, here, do not read this article that has cushioning effect and do the concrete limit.

Optionally, one end of the placing cavity 11 arranged on the shell 1 is provided with an opening shape, and the other end is provided with a closed shape; the placing cavity 11 is provided with a plurality of buffer assemblies 2, and the supporting plate 21 is detachably connected with the placing plate 3.

In this application embodiment, place chamber 11 one end and set up to the opening shape, the other end sets up to the closed shape, mainly is placed from one end in order to make things convenient for reserve battery 4, and the other end sets up to the closed shape, and then can make the storage battery place on the board 3, play certain limiting displacement, and placed a plurality of buffer assembly 2 in placing chamber 11, in this application, five buffer assembly 2 have mainly been placed in placing chamber 11, the four corners and the intermediate position of placing chamber 11 are distributed respectively, a plurality of buffer assembly 2 have been placed, the cushioning effect to placing board 3 is more obvious.

Optionally, a first chute and a second chute are provided on the accommodating cavity 24, one end of the first buffer column 22 is connected with the bottom of the supporting plate 21, the other end of the first buffer column 22 is movably installed in the first chute, one end of the second buffer column 23 is connected with the bottom of the supporting plate 21, and the other end of the second buffer column 23 is movably installed in the second chute; the first sliding groove is connected with the first buffer post 22, and the second sliding groove is connected with the second buffer post 23 in a clearance fit manner.

Alternatively, the cross-sectional area of the placement chamber 11 is larger than the cross-sectional area of the support plate 21; one end of the spring 25 is connected with the bottom of the supporting plate 21, and the other end of the spring 25 is arranged at the bottom of the accommodating cavity 24; the placing plate 3 is provided with coamings, the coamings are arranged on two sides and one end of the placing plate 3, and the other end of the placing plate 3 is in an opening shape; the height of the coaming is set to be a preset value, and the coaming and the placing plate 3 are integrally formed.

In the embodiment of the present application, it should be noted that the coaming and the placing plate 3 are integrally formed, that is, the coaming and the placing plate 3 are connected in a non-detachable connection relationship.

The above disclosed features are not limited to the disclosed combinations with other features, and other combinations between features can be made by those skilled in the art according to the purpose of the utility model to achieve the purpose of the utility model.

Claims (10)

1. An energy storage power station battery package buffer structure, characterized by comprising: a housing, a cushioning assembly, and a placement plate;

the shell is provided with a placing cavity, the buffer assembly is installed in the placing cavity, the placing plate is placed on the buffer assembly, the buffer assembly comprises a buffer shell, a first buffer column, a second buffer column, a spring and a support plate, the support plate is connected with the first buffer column, the second buffer column and the spring, the placing plate is connected with the support plate, the buffer shell is provided with a containing cavity, and the spring, the first buffer column and the second buffer column are installed in the containing cavity; the placing plate is used for placing a reserve battery, and the first buffer column, the second buffer column and the spring are used for buffering the weight applied to the supporting plate.

2. The buffer structure of a battery pack of an energy storage power station according to claim 1, wherein a soft sponge is placed on the upper surface of the placement plate, anti-slip stripes are arranged on the soft sponge, and the soft sponge is detachably connected with the placement plate.

3. The buffering structure for the battery pack of the energy storage power station according to claim 1, wherein one end of a placing cavity arranged on the shell is in an opening shape, and the other end of the placing cavity is in a closed shape.

4. The buffer structure of an energy storage power station battery pack according to claim 3, wherein a plurality of buffer assemblies are placed in the placement cavity, and the support plate is detachably connected with the placement plate.

5. The energy storage power station battery pack buffer structure according to claim 1, wherein a first chute and a second chute are arranged on the accommodating cavity, one end of the first buffer column is connected with the bottom of the supporting plate, the other end of the first buffer column is movably installed in the first chute, one end of the second buffer column is connected with the bottom of the supporting plate, and the other end of the second buffer column is movably installed in the second chute.

6. The buffer structure of claim 5, wherein the first chute is connected to the first buffer post and the second chute is connected to the second buffer post in a clearance fit.

7. The energy storage power station cell pack cushioning structure of any one of claims 1-6, wherein the placement cavity has a cross-sectional area greater than the cross-sectional area of the support plate.

8. The buffering structure for the battery pack of the energy storage power station according to claim 7, wherein one end of the spring is connected with the bottom of the supporting plate, and the other end of the spring is installed at the bottom of the accommodating cavity.

9. The buffering structure for the battery pack of the energy storage power station according to claim 1, wherein the enclosing plates are arranged on the placing plate, the enclosing plates are arranged on two sides and one end of the placing plate, and the other end of the placing plate is in an opening shape.

10. The energy storage power station battery pack buffer structure according to claim 9, wherein the height of the coaming is set to a preset value, and the coaming and the placing plate are integrally formed.