CN220155680U - Battery pack installing support, energy storage cluster and energy storage cabinet - Google Patents

Abstract

The utility model provides a battery pack mounting bracket, which comprises a frame, wherein the frame comprises two groups of side frames which are connected, and an inlet side for transversely mounting a battery pack and a stop side opposite to the inlet side are formed between the two groups of side frames; a plurality of layers of mounting positions for placing the battery packs are vertically arranged in the frame, each layer of mounting positions comprises two supporting beams which are oppositely arranged, the supporting beams are arranged on the side frames, the supporting beams of each layer of mounting positions can be vertically adjusted relative to the side frames, and the first position and the second position are switched; when the supporting beam is positioned at the first position, the height of the supporting beam at the inlet side is the same as the height of the stopping side; when the supporting beam is located at the second position, the height of the supporting beam at the inlet side is higher than that at the stop side. Compared with the prior art, through the switching of supporting beam position in this scheme, make the battery package slide in through its own gravity when putting into the installation position, and then make the installation operation of battery package easy operation, save trouble laborsaving.

Description

Battery pack installing support, energy storage cluster and energy storage cabinet

Technical Field

The utility model belongs to the technical field of battery energy storage equipment, and particularly relates to a battery pack mounting bracket.

Background

The weight and the volume of the energy storage battery pack in the current mainstream are large, the energy storage battery pack is not well hoisted into an energy storage cabinet when being installed, and the space size of the energy storage cabinet can be limited when a forklift is used for hoisting, so that the operation process of packaging the battery into the energy storage cabinet is very tedious and laborious; and the outside of the battery pack is very easy to scratch in the installation process, so that the quality of the battery pack is influenced. In addition, when the battery pack is detached from the energy storage cabinet, the battery pack is inconvenient to use, and the detachment process is complex and laborious to operate.

Disclosure of Invention

In view of the above-mentioned drawbacks of the prior art, an object of the present utility model is to provide a battery pack mounting bracket for solving the problem of complicated and laborious operation of placing a battery pack into the bracket in the prior art.

To achieve the above object and other related objects, the present utility model provides the following technical solutions:

a battery pack mounting bracket comprising:

a frame including two sets of side frames connected to each other, an inlet side for lateral loading of the battery pack and a stopper side opposite to the inlet side being formed between the two sets of side frames;

a plurality of layers of mounting positions for placing battery packs are vertically arranged in the frame, each layer of mounting positions comprises two supporting beams which are oppositely arranged, the supporting beams are arranged on the side frames, the supporting beams of each layer of mounting positions can be adjusted up and down relative to the side frames, and the first position and the second position are switched;

when the supporting cross beam is positioned at the first position, the height of the supporting cross beam at the inlet side is the same as the height of the stopping side; when the supporting beam is located at the second position, the height of the supporting beam on the inlet side is higher than that on the stop side.

Optionally, the supporting beam further has a third position on the side frame, and when the supporting beam is located at the third position, the supporting beam is lower in height on the inlet side than on the stop side.

Optionally, the supporting beam has at least two connection positions with the side frame in the length direction, the supporting beam is rotatably connected with the side frame at one connection position, and the other connection position can be adjusted up and down relative to the side frame and locked at the adjusted position.

Optionally, the two supporting beams of each group of installation positions are rotatably connected with the side frame at one end close to the inlet side, and one end close to the stop side is adjusted up and down with the side frame; or the two supporting crossbeams of each group of installation positions are adjusted up and down with the side frame at one end close to the inlet side, and one end close to the stop side is connected with the side frame in a rotating way.

Optionally, each set of side frames includes a first longitudinal beam near the inlet side and a second longitudinal beam near the stop side, and one end of the supporting cross beam is rotatably connected with the second longitudinal beam through a rotating pin; at least two adjusting positions are vertically arranged on the first longitudinal beam, and the other end of the supporting cross beam and the first longitudinal beam are arranged at one of the adjusting positions through a locking part and can be switched up and down between the adjusting positions.

Optionally, the adjustment position includes two at least horizontal grooves that vertical interval set up and the vertical groove that communicates with each horizontal groove, locking part for can vertical groove with the gliding slip round pin between the horizontal groove, be provided with on the supporting beam and be used for the slip round pin inserts and gliding spout.

Optionally, the number of the transverse grooves is three, and the height of the transverse groove above is higher than that of the transverse groove near the inlet side than that near the stop side; the transverse groove in the middle is in a horizontal position; the height of the transverse groove below is lower than the height of the transverse groove near the inlet side than the height near the stop side.

Optionally, the side frame further includes a middle longitudinal beam located between the first longitudinal beam and the second longitudinal beam, and at least two adjusting positions are arranged on the middle longitudinal beam.

Optionally, the battery pack mounting device further comprises a limiting part, wherein the limiting part is used for limiting the position of the battery pack in the mounting position, and the limiting part is a limiting longitudinal beam arranged on the side of the stop position or a limiting plate arranged on the battery pack and matched with the inlet side.

Correspondingly, the utility model also provides an energy storage cluster, which comprises:

a plurality of battery packs;

a battery pack mounting bracket, the battery pack mounting bracket being any one of the battery pack mounting brackets described above;

wherein each layer of the installation position is provided with the battery pack.

Correspondingly, the utility model also provides an energy storage cabinet, which comprises:

and the energy storage clusters are the energy storage clusters.

In the utility model, a battery pack mounting bracket is arranged in an energy storage cabinet, and an inlet side is opposite to an inlet side of the energy storage cabinet; then, the supporting beam is adjusted to a second position, so that the supporting beam is in an inclined state, and is inclined from the inlet side towards the anti-position side, and when the battery pack is transversely arranged in the battery pack from the inlet side, the battery pack can slide into the mounting position along the supporting beam under the action of gravity; the battery pack is arranged in the energy storage cabinet, so that the operation is simple, time and labor are saved, tools are not needed to put the battery pack into the energy storage cabinet, the external part of the battery pack is prevented from being scratched and damaged, and the quality of the battery pack is ensured; after the battery pack is placed in one layer of installation position, the supporting beam can be switched to the first position, so that the supporting beam is in a horizontal state, and the battery pack is in a horizontal position in the bracket. Compared with the prior art, the battery pack mounting bracket in the scheme enables the battery pack to slide in through self gravity when being placed in the mounting position through the switching of the positions of the supporting beams, and further enables the mounting process of the battery pack to be simple in operation and labor-saving.

Drawings

Fig. 1 is a schematic view showing the structure of a battery pack mounting bracket according to an example of the present utility model;

FIG. 2 is a side view of an exemplary battery pack mounting bracket of the present utility model;

FIG. 3 is an enlarged view of FIG. 1 at A;

FIG. 4 is a schematic view of a support beam in a first position in a battery pack mounting bracket of an example of the present utility model;

FIG. 5 is a schematic view of a support beam in a second position in a battery pack mounting bracket of an example of the utility model;

FIG. 6 is a schematic view of a support beam in a third position in a battery pack mounting bracket of an example of the present utility model;

FIG. 7 is a schematic diagram of an exemplary energy storage cluster of the present utility model;

FIG. 8 is a front view of an exemplary energy storage cluster of the present utility model;

fig. 9 is a schematic structural diagram of an exemplary energy storage cabinet according to the present utility model.

The reference numerals in the embodiments include:

side frame 10, first longitudinal beam 11, middle longitudinal beam 12, second longitudinal beam 13, connecting cross beam 14,

An inlet side 20, a stop side 21, a limiting longitudinal beam 22, a vertical groove 23, a transverse groove 24,

A supporting beam 30, a chute 31, a rotary pin 32, a sliding pin 33,

And a battery pack 40.

Detailed Description

In the following description, numerous specific details are set forth in order to provide a more thorough understanding of the present utility model. It will be apparent, however, to one skilled in the art that the utility model may be practiced without one or more of these details. In other instances, well-known features have not been described in detail in order to avoid obscuring the utility model.

It should be understood that the present utility model may be embodied in various forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the utility model to those skilled in the art. In the drawings, like numbers refer to like elements throughout.

In the utility model, as shown in fig. 9, the energy storage cabinet consists of an energy storage cluster(s), a box body, a battery management system, related installation structural members and the like, and can be widely applied to multiple fields of small-sized solar power stations, UPS (uninterrupted Power supply), electric vehicles, wind power generation and the like. As shown in fig. 7 and fig. 8, the energy storage cluster includes a battery pack mounting bracket and a plurality of battery packs 40, wherein a plurality of layers of mounting positions are vertically arranged in the battery pack mounting bracket, and the battery packs 40 are transversely mounted in the mounting positions from one side of the bracket, and the battery pack mounting bracket may be any of the battery pack mounting brackets in the following embodiments.

Referring to fig. 1 and 6 in combination, the specific structure of the battery pack mounting bracket of the present utility model includes:

a frame including two sets of side frames 10 connected to each other, an inlet side 20 for the lateral loading of the battery pack 40 and a stopper side 21 opposite to the inlet side 20 being formed between the two sets of side frames 10;

a plurality of layers of mounting positions for placing the battery packs 40 are vertically arranged in the frame, each layer of mounting positions comprises two supporting beams 30 which are oppositely arranged, the supporting beams 30 are arranged on the side frames 10, the supporting beams 30 of each layer of mounting positions can be adjusted up and down relative to the side frames 10, and the first position and the second position are switched;

wherein, when the supporting beam 30 is positioned at the first position, the height of the supporting beam 30 at the inlet side 20 is the same as the height of the stopping side 21; when the support beam 30 is in the second position, the support beam 30 has a higher height at the inlet side 20 than at the stop side 21.

Specifically, the two groups of side frames 10 are fixedly connected through a connecting cross beam 14, and a stable hollow frame structure is formed through the side frames 10 and the connecting cross beam 14. The side of the support beam 30 facing the inside of the frame has a support portion on which both sides of the lower end of the battery pack 40 can be placed. The supporting beam 30 is switched between a first position and a second position, mainly the state of the supporting beam 30 along the horizontal direction is switched, wherein the supporting beam 30 is in the horizontal state when in the first position; in the second position, the support beam 30 is inclined in a direction from the entrance side 20 toward the stopper side 21. The support beam 30 may be switched between the first position and the second position by locking after rotation, or by locking after positioning, or the like.

In practical implementation, the battery pack mounting bracket in this embodiment is placed in the tank of the energy storage cabinet, where the inlet side 20 is aligned with the inlet side 20 of the tank, and when the battery pack 40 is mounted in the bracket, the support beams 30 are adjusted to the second position, as shown by the two uppermost support beams 30 in fig. 1 and the support beams 30 in fig. 5, so that the support beams 30 are in an inclined state and are inclined from the inlet side 20 toward the stop side 21; when the battery pack 40 is laterally loaded from the inlet side 20, the battery pack 40 can slide along the support beam 30 into the interior of the mounting location; when the battery is slid into the mounting position, the support beam 30 is switched to the first position, as shown by the support beam 30 in fig. 4, so that the support beam 30 is in a horizontal state, and the battery pack 40 is in a horizontal position in the rack. After the battery pack 40 is installed in the above manner, the bracket can form an energy storage cluster filled with the battery pack 40, and the energy storage cluster is positioned in the energy storage cabinet and matched with a structure in the energy storage cabinet to store energy. Through this support installation battery package 40, can make the process easy operation of battery package 40 installation in the energy storage cabinet, labour saving and time saving, and need not the instrument and put into the energy storage cabinet inside with battery package 40, this just has avoided the outside of battery package 40 to be scraped to scratch impaired, has guaranteed the quality of battery package 40.

In some embodiments, the support beam 30 further has a third position on the side frame 10, the support beam 30 having a lower height at the inlet side 20 than at the stop side 21 when the support beam 30 is in the third position.

In the specific implementation, the third and fourth support beams 30 are in the third position from top to bottom in fig. 1, and the support beams 30 are in the third position in fig. 6, the support beams 30 in the third position being inclined from the stop side 21 toward the inlet side 20; when the battery pack 40 in the energy storage cabinet needs to be disassembled, the supporting beam 30 can be adjusted to be in a third state, and due to the inclination of the supporting beam 30, the battery pack 40 can slide out of the battery pack mounting bracket from the stop side 21 to the inlet side 20 under the action of self gravity, so that the battery pack 40 can be disassembled quickly and in a labor-saving mode.

In some embodiments, the supporting beam 30 has at least two connection points with the side frame 10 along its length, and the supporting beam 30 is rotatably connected with the side frame 10 at one of the connection points, and is vertically adjustable and locked at the adjusted position with respect to the side frame 10 at the other connection point. When the supporting beam 30 is switched between the first position and the second position, the supporting beam 30 can be adjusted up and down along one of the links, the supporting beam 30 is rotated along the other link, and the supporting beam 30 is locked after the position is adjusted, so that the supporting beam 30 is positioned at the first position or the second position; the mode realizes the switching of the positions of the supporting beams 30, is simple to operate, and can rapidly lock the supporting beams 30.

In some embodiments, the two support beams 30 of each set of mounting locations are rotatably connected to the side frame 10 at one end near the inlet side 20 and are adjusted up and down with the side frame 10 at one end near the stop side 21; or the two supporting beams 30 of each group of installation positions are adjusted up and down with the side frame 10 at one end near the inlet side 20, and one end near the stop side 21 is connected with the side frame 10 in a rotating way. For example, as shown in fig. 1 to 6, the connection position adjusted vertically is provided on the stopper side 21, the connection position adjusted in rotation is provided on the inlet side 20, and the operation is performed on the stopper side 21 when the position state of the support beam 30 is switched. Alternatively, the connection position of the rotary connection is provided on the stopper side 21, and the connection position of the vertical adjustment is provided on the inlet side 20, so that the operation can be performed on the inlet side 20 when the position state of the support beam 30 is switched, and the operation of the mounting process of the battery pack 40 can be further simplified.

In some embodiments, each set of said side frames 10 comprises a first longitudinal beam 11 adjacent to said inlet side 20 and a second longitudinal beam 13 adjacent to said stop side 21, one end of said support cross beam 30 being pivotally connected to said second longitudinal beam 13 by a pivot pin 32; at least two adjusting positions are vertically arranged on the first longitudinal beam 11, and the other end of the supporting cross beam 30 and the first longitudinal beam 11 are arranged at one of the adjusting positions through a locking component and can be switched up and down between the adjusting positions.

In the practical implementation process, as shown in fig. 1-6, the side frame 10 is provided with a first longitudinal beam 11 and a second longitudinal beam 13, one end of the supporting cross beam 30 is rotatably connected with the second longitudinal beam 13, and the other end of the supporting cross beam 30 is in different adjusting positions through the locking component, so that the up-and-down adjustment along the first longitudinal beam 11 is realized.

In some embodiments, the adjusting position includes at least two transverse grooves 24 arranged at intervals vertically and a vertical groove 23 communicated with each transverse groove 24, the locking component is a sliding pin 33 capable of sliding between the vertical groove 23 and the transverse groove 24, and a sliding groove 31 for inserting and sliding the sliding pin 33 is arranged on the supporting beam 30. For example, as shown in fig. 1-6, switching the sliding pin 33 into a different transverse slot 24 may effect switching of the support beam 30 to a different position; to facilitate sliding of the sliding pin 33 into the different transverse grooves 24, the transverse grooves 24 are connected by means of the vertical grooves 23; in order to enable the sliding pin 33 to slide smoothly in the lateral groove 24 and the vertical groove 23, the sliding pin 33 is horizontally slidably connected to the support beam 30 through the slide groove 31.

In some embodiments, the lateral grooves 24 are three arranged up and down, and the height of the lateral groove 24 located above is higher near the inlet side 20 than near the stop side 21; the centrally located lateral slot 24 is in a horizontal position; the height of the transverse groove 24 located below is lower near the inlet side 20 than near the stop side 21. In the specific implementation, as shown in fig. 4, the sliding pin 33 slides along the vertical slot 23 into the middle transverse slot 24 to support the cross beam 30 in the first position; as shown in fig. 5, sliding the sliding pin 33 along the vertical slot 23 into the upper lateral slot 24 supports the cross beam 30 in the second position; as shown in fig. 6, sliding the sliding pin 33 along the vertical slot 23 into the middle lateral slot 24 supports the cross beam 30 in the third position. The three transverse grooves 24 are arranged at different angles so that the sliding direction of the transverse grooves 24 and the rotation connection of the rotary pin 32 are on the same straight line, and therefore, when the position of the supporting beam 30 is adjusted through the sliding pin 33, the adjustment can be smoothly performed. In this embodiment, the vertical slot 23 may be connected to the end of the lateral slot 24 near the inlet side 20, and the sliding pin 33 may be locked by matching with the lateral slot 24 in accordance with the inclination of each lateral slot 24, without any other locking structure.

In some embodiments, the side frame 10 further includes a middle rail 12 located between the first rail 11 and the second rail 13, and at least two adjustment positions are provided on the middle rail 12. For example, as shown in fig. 4 to 6, the adjustment position provided on the intermediate side member 12 is set with reference to the adjustment position of the first side member 11, which also includes the lateral groove 24 and the vertical groove 23, wherein the lateral groove 24 above the adjustment position is aligned with the lateral groove 24 above the first side member 11, the lateral groove 24 in the middle of the adjustment position is aligned with the lateral groove 24 in the middle of the first side member 11, and the lateral groove 24 below the adjustment position is aligned with the lateral groove 24 below the first side member 11.

In some embodiments, the battery pack 40 is further provided with a limiting member for limiting the position of the battery pack 40 in the installation position, wherein the limiting member is a limiting longitudinal beam 22 arranged on the stop side 21, or is a limiting plate arranged on the battery pack 40 and matched with the inlet side 20.

In the embodiment, when the battery pack 40 is mounted in the mounting position, the weight of the battery pack 40 is used to slide the battery pack 40 along the inclined support beam 30 from the inlet side 20 into the mounting position, and then after the battery pack 40 is completely mounted in the mounting position, the battery pack 40 needs to be limited to prevent the battery pack 40 from sliding out of the stop side 21. In this scheme, the limiting piece is arranged to limit the battery pack 40, specifically, the limiting piece can be arranged at the stop side 21 to block the battery pack 40, as shown in fig. 1, after the battery pack 40 completely enters the installation position, the battery pack is not slid along the supporting cross beam 30 under the blocking of the limiting longitudinal beam 22; a limiting plate may be disposed on the rear side of the battery pack 40 (the side of the battery pack 40 that enters the mounting position is the front side, and the opposite side is the rear side), the width of the limiting plate is greater than the width between the two first stringers 11, and after the battery pack 40 completely enters the mounting position, the limiting plate is blocked by the two first stringers 11, so that the battery pack 40 does not slide along the support cross beam 30.

The above embodiments are merely illustrative of the principles of the present utility model and its effectiveness, and are not intended to limit the utility model. Modifications and variations may be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the utility model. Accordingly, it is intended that all equivalent modifications and variations of the utility model be covered by the claims, which are within the ordinary skill of the art, be within the spirit and scope of the present disclosure.

Claims (11)

1. A battery pack mounting bracket, comprising:

a frame including two sets of side frames connected to each other, an inlet side for lateral loading of the battery pack and a stopper side opposite to the inlet side being formed between the two sets of side frames;

a plurality of layers of mounting positions for placing battery packs are vertically arranged in the frame, each layer of mounting positions comprises two supporting beams which are oppositely arranged, the supporting beams are arranged on the side frames, the supporting beams of each layer of mounting positions can be adjusted up and down relative to the side frames, and the first position and the second position are switched;

when the supporting cross beam is positioned at the first position, the height of the supporting cross beam at the inlet side is the same as the height of the stopping side; when the supporting beam is located at the second position, the height of the supporting beam on the inlet side is higher than that on the stop side.

2. The battery pack mounting bracket of claim 1 wherein: the supporting cross beam is further provided with a third position on the side frame, and when the supporting cross beam is positioned at the third position, the height of the supporting cross beam at the inlet side is lower than the height of the supporting cross beam at the stop side.

3. The battery pack mounting bracket of claim 1 wherein: the supporting cross beam and the side frame are rotatably connected at one connecting position, and the other connecting position can be adjusted up and down relative to the side frame and locked at the adjusted position.

4. The battery pack mounting bracket of claim 3, wherein: the two supporting beams of each group of installation positions are rotatably connected with the side frame at one end close to the inlet side, and one end close to the stop side is adjusted up and down with the side frame; or the two supporting crossbeams of each group of installation positions are adjusted up and down with the side frame at one end close to the inlet side, and one end close to the stop side is connected with the side frame in a rotating way.

5. The battery pack mounting bracket of claim 4, wherein: each group of side frames comprises a first longitudinal beam close to the inlet side and a second longitudinal beam close to the stop side, and one end of the supporting cross beam is rotationally connected with the second longitudinal beam through a rotating pin; at least two adjusting positions are vertically arranged on the first longitudinal beam, and the other end of the supporting cross beam and the first longitudinal beam are arranged at one of the adjusting positions through a locking part and can be switched up and down between the adjusting positions.

6. The battery pack mounting bracket of claim 5, wherein: the adjusting position comprises at least two transverse grooves arranged at vertical intervals and vertical grooves communicated with the transverse grooves, the locking part is a sliding pin capable of sliding between the vertical grooves and the transverse grooves, and the supporting cross beam is provided with a sliding groove for inserting and sliding the sliding pin.

7. The battery pack mounting bracket of claim 6 wherein: the transverse grooves are three arranged up and down, and the height of the upper transverse groove close to the inlet side is higher than the height of the upper transverse groove close to the stop side; the transverse groove in the middle is in a horizontal position; the height of the transverse groove below is lower than the height of the transverse groove near the inlet side than the height near the stop side.

8. The battery pack mounting bracket of claim 5, wherein: the side frame further comprises a middle longitudinal beam positioned between the first longitudinal beam and the second longitudinal beam, and at least two adjusting positions are arranged on the middle longitudinal beam.

9. The battery pack mounting bracket of any of claims 1-8 wherein: the battery pack mounting device comprises a mounting position, and is characterized by further comprising a limiting piece, wherein the limiting piece is used for limiting the position of the battery pack in the mounting position, and the limiting piece is a limiting longitudinal beam arranged on the side of the stop position, or is a limiting plate arranged on the battery pack and matched with the inlet side.

10. An energy storage cluster, comprising:

a plurality of battery packs;

a battery pack mounting bracket of any one of claims 1-9;

wherein each layer of the installation position is provided with the battery pack.

11. An energy storage cabinet, comprising:

a storage cluster, said storage cluster being the storage cluster of claim 10.