CN217062332U - Energy storage frame and energy storage equipment - Google Patents

Abstract

The application provides an energy storage frame and energy storage equipment, wherein, the energy storage frame includes: a frame body and a plurality of guide assemblies. The support body includes a plurality of structures, is provided with the mounting hole on the part structure. The fixing part of the guide assembly is positioned in the mounting hole, one end of the fixing part extends out of one side face of the structural part, and the other end of the fixing part is fixedly connected with the other side face of the structural part. The application provides an energy storage frame, insert the in-process of installation cavity at the battery subrack, the direction subassembly receives the impact force of battery subrack, because the part of fixed part is located the mounting hole, the pore wall of mounting hole can provide the holding power for the fixed part, this holding power offsets partial impact force, another impact force acts on the junction of fixed part and structure, thereby the size that the junction of fixed part and structure received the impact force has been reduced, the ability of direction subassembly impact resistance has been improved, joint strength between fixed part and the structure has been guaranteed, and then the use reliability of energy storage frame has been improved.

Description

Energy storage frame and energy storage equipment

Technical Field

The application relates to the technical field of batteries, in particular to an energy storage rack and energy storage equipment.

Background

The energy storage equipment is a new energy equipment which stores a large number of energy storage lithium batteries in the frame, a plurality of accommodating cavities are arranged in the frame, each accommodating cavity is provided with a battery plug box, each accommodating cavity is provided with a guide structure on the side wall of the corresponding accommodating cavity, and the guide structures play a role in guiding the battery plug boxes so that the battery plug boxes can be inserted or pulled out more smoothly in the accommodating cavity. However, due to the heavy weight of the battery box, the guide structure is subject to a large impact force during the process of inserting or pulling the battery box into or out of the accommodating cavity, so that the guide structure is easily damaged.

SUMMERY OF THE UTILITY MODEL

The application aims to provide an energy storage frame and energy storage equipment which are high in installation strength and good in shock resistance.

To achieve the above object, an embodiment of a first aspect of the present application provides an energy storage rack, including: the frame body is a frame structure formed by a plurality of structural members, and mounting holes are formed in part of the structural members; and a plurality of guide assemblies secured to the structural member and positioned within the mounting holes, the guide assemblies configured to guide movement of a battery receptacle; wherein, the guide assembly includes: the fixing part is positioned in the mounting hole, one end of the fixing part extends out of one side face of the structural part, and the other end of the fixing part is fixedly connected with the other side face of the structural part; and the guide part is rotatably arranged on the fixing part and is positioned at one end of the fixing part.

Compared with the prior art, the technical scheme has the following advantages:

in the process of inserting the battery plug box into the installation cavity, the guide assembly receives the impact force of the battery plug box, because the part of the fixed part is located in the installation hole, the fixed part contacts with the hole wall of the installation hole, the hole wall of the installation hole can provide supporting force for the fixed part, the supporting force offsets partial impact force, another impact force acts on the joint of the fixed part and the structural part, thereby reducing the impact force received by the joint of the fixed part and the structural part, the anti-impact force capability of the guide assembly is improved, the connection strength between the fixed part and the structural part is ensured, and further the connection reliability between the fixed part and the structural part is ensured, the probability of separation between the fixed part and the structural part is reduced, and the service life of a product is prolonged.

Embodiments of the second aspect of the present application provide an energy storage device, including a plurality of battery subracks and the above-mentioned energy storage frame, the battery subrack is installed in the energy storage frame.

Compared with the prior art, the technical scheme has the following advantages:

the energy storage equipment is high in installation strength and good in impact resistance, so that the use reliability of the energy storage equipment is improved, the service life of a product is prolonged, and the market competitiveness of the product is increased.

Drawings

The drawings are only for purposes of illustrating and explaining the present application and are not to be construed as limiting the scope of the present application. Wherein:

FIG. 1 is a schematic structural view of an energy storage rack of the present application;

FIG. 2 is a schematic view of a portion of the energy storage rack of FIG. 1;

FIG. 3 is a partial schematic structural view of a first embodiment of a guide assembly of the present application in cooperation with a post;

FIG. 4 is a cross-sectional structural schematic of the structure shown in FIG. 3;

FIG. 5 is a schematic view, partially in section, of a second embodiment of a guide assembly of the present application in cooperation with a post;

FIG. 6 is a schematic structural view of a steering assembly of the present application;

fig. 7 is a partial structural schematic diagram of an energy storage device according to the present application.

The reference numbers indicate:

10. a frame body; 11. a structural member; 12. a mounting cavity; 13. mounting holes; 14. mounting grooves; 15. a column; 16. a cross beam; 17. an oblique beam; 20. a guide assembly; 21. a fixed part; 211. a mounting frame; 212. a connecting plate; 213. reinforcing ribs; 22. a guide portion; 221. a connecting shaft; 222. a guide roller; 30. a nut; 40. a screw; 100. an energy storage rack; 200. and (4) inserting a battery into the box.

Detailed Description

The present application will be described in further detail below with reference to the accompanying drawings and examples. The features and advantages of the present application will become more apparent from the description.

The word "exemplary" is used exclusively herein to mean "serving as an example, embodiment, or illustration. Any embodiment described herein as "exemplary" is not necessarily to be construed as preferred or advantageous over other embodiments. While the various aspects of the embodiments are presented in drawings, the drawings are not necessarily drawn to scale unless specifically indicated.

In addition, the technical features described below in the different embodiments of the present application may be combined with each other as long as they do not conflict with each other. The following discussion provides a number of embodiments of the present application. While each embodiment represents a single combination of applications, the various embodiments of the disclosure may be substituted or combined in any combination, and thus, the disclosure is intended to include all possible combinations of the same and/or different embodiments of what is described. Thus, if one embodiment comprises A, B, C and another embodiment comprises a combination of B and D, then this application should also be considered to comprise an embodiment that comprises A, B, C, D in all other possible combinations, although this embodiment may not be explicitly recited in the text below. In addition, the technical features related to the different embodiments of the present application described below may be combined with each other as long as they do not conflict with each other.

As shown in fig. 1 to 3, an embodiment of the first aspect of the present application provides an energy storage rack 100 including: a frame body 10 and a plurality of guide assemblies 20.

The frame body 10 is a frame structure formed by a plurality of structural members 11, a mounting hole 13 is formed in a part of the structural members 11, and the frame body 10 has a plurality of mounting cavities 12 for accommodating the battery insert boxes 200.

A plurality of guide assemblies 20 are secured to the structural member 11 and positioned within the mounting holes 13, the guide assemblies configured to guide movement of the battery compartment 200.

The guide assembly 20 includes: a fixing portion 21 and a guide portion 22.

The fixing part 21 is positioned in the mounting hole 13, one end of the fixing part 21 extends out of one side surface of the structural part 11, and the other end of the fixing part 21 is fixedly connected with the other side surface of the structural part 11; specifically, one end of the fixing portion 21 extends into the mounting cavity 12 through the mounting hole 13, and the other end of the fixing portion 21 is located outside the mounting cavity 12 and is fixedly connected to the structural member 11.

The guide portion 22 is rotatably mounted on the fixing portion 21 and located at one end of the fixing portion 21, specifically, the guide portion 22 is rotatably mounted on the fixing portion 21, and the guide portion 22 is located in the mounting cavity 12.

The utility model provides an energy storage frame 100, in-process that battery subrack 200 inserted installation cavity 12, direction subassembly 20 receives battery subrack 200's impact force, because the part of fixed part 21 is located mounting hole 13, fixed part 21 and mounting hole 13's pore wall contact, mounting hole 13's pore wall can provide the holding power for fixed part 21, this holding power offsets partial impact force, another part impact force acts on the junction of fixed part 21 and structure 11, thereby the size that the junction of fixed part 21 and structure 11 received the impact force has been reduced, the ability of direction subassembly 20 anti-impact force has been improved, joint strength between fixed part 21 and the structure 11 has been guaranteed, and then the connection reliability between fixed part 21 and the structure 11 has been guaranteed, the probability of taking place the separation between fixed part 21 and the structure 11 has been reduced, the life of product has been prolonged.

As shown in fig. 1, in one embodiment of the present application, the structural member 11 includes a vertically disposed upright 15 and a horizontally disposed cross member 16, and the guide assembly 20 is disposed on the upright 15; specifically, the frame body 10 is composed of a plurality of vertically arranged vertical columns 15 and a plurality of horizontally arranged cross beams 16, and the plurality of vertical columns 15 and the plurality of cross beams 16 are connected to form a plurality of installation cavities 12. In one embodiment of the present application, two ends of each cross beam 16 are respectively connected to two columns 15, the columns 15 are perpendicular to the cross beams 16, and the columns 15 and the cross beams 16 enclose a mounting cavity 12 for accommodating the battery compartment 200. In a preferred embodiment of the present application, the energy storage rack 100 further includes an oblique beam 17, two ends of the oblique beam 17 are respectively connected to the two upright posts 15, and the oblique beam 17 is disposed obliquely relative to the upright posts 15, and the disposition of the oblique beam 17 increases the overall strength of the energy storage rack 100.

As shown in fig. 1, in one embodiment of the present application, a plurality of guide assemblies 20 are provided in pairs on two structural members 11; that is, a guide assembly 20 is disposed on the symmetrically disposed walls of each mounting cavity 12.

With the above arrangement, in the process of inserting the battery box 200 into the installation cavity 12, both sides of the battery box 200 are guided by the guide assemblies 20, so that the battery box 200 is uniformly stressed, and the battery box 200 is smoothly inserted into the installation cavity 12.

As shown in fig. 4 to 6, in one embodiment of the present application, the fixing portion 21 includes: mounting bracket 211 and connecting plate 212.

The mounting bracket 211 is located in the mounting hole 13, one end of the mounting bracket 211 extends out of one side of the structural member 11, and the other end of the mounting bracket 211 is fixedly connected to the other side of the structural member 11, specifically, one end of the mounting bracket 211 passes through the mounting hole 13 and extends into the mounting cavity 12.

The connection plate 212 is disposed on the other end of the mounting bracket 211 and is fixedly connected to the structural member 11.

The connecting plate 212 enables the fixing portion 21 and the structural member 11 to be connected in a surface-to-surface mode, so that the connecting area between the fixing portion 21 and the structural member 11 is increased, the connecting strength between the fixing portion 21 and the structural member 11 is guaranteed, the impact resistance of the guide assembly 20 is further improved, the connection reliability between the fixing portion 21 and the structural member 11 is further guaranteed, the probability of separation between the fixing portion 21 and the structural member 11 is reduced, the service life of a product is prolonged, and the long-time competitiveness of the product is increased.

As shown in fig. 4 to 6, in one embodiment of the present application, the guide portion 22 includes a connection shaft 221 and a guide roller 222; the connecting shaft 221 is fixedly connected with the mounting frame 211, and the guide roller 222 is rotatably connected with the connecting shaft 221; when the battery box 200 is inserted into the mounting cavity 12, the battery box 200 drives the guide roller 222 to rotate relative to the connecting shaft 221, so that the guide roller 222 is smoothly inserted into the mounting cavity 12. Or, the connecting shaft 221 is rotatably connected with the mounting frame 211, the guide roller 222 is fixedly connected with the connecting shaft 221, and when the battery inserting box 200 is inserted into the mounting cavity 12, the battery inserting box 200 drives the guide roller 222 to enable the connecting shaft 221 to rotate relative to the mounting frame 211, so that the guide roller 222 is smoothly inserted into the mounting cavity 12.

As shown in fig. 4 to 6, in one embodiment of the present application, two connection plates 212 are symmetrically disposed at both sides of the mounting bracket 211.

The connecting plates 212 symmetrically arranged ensure the uniformity of the stress of the fixing part 21, and when the fixing part receives impact force, the force received by the fixing part 21 can be uniformly transmitted to the structural part 11, so that the impact resistance of the guide assembly 20 is improved, the connection reliability between the fixing part 21 and the structural part 11 is ensured, the probability of separation between the fixing part 21 and the structural part 11 is reduced, the service life of a product is prolonged, and the long-term competitiveness of the product is increased.

As shown in fig. 5, in one embodiment of the present application, the structural member 11 is provided with a mounting groove 14, and the connection plate 212 is fixed in the mounting groove 14.

On one hand, the mounting groove 14 plays a positioning role, so that the connecting plate 212 can be quickly and accurately mounted on the structural member 11, even if the fixing part 21 is quickly and accurately mounted on the structural member 11, thereby improving the assembly efficiency of the energy storage rack 100 and reducing the production and manufacturing cost of products. On the other hand, the connecting area between the connecting plate 212 and the structural member 11 is further increased, the connecting strength between the fixing portion 21 and the structural member 11 is further ensured, the impact resistance of the guide assembly 20 is further improved, the connection reliability between the fixing portion 21 and the structural member 11 is further ensured, the probability of separation between the fixing portion 21 and the structural member 11 is reduced, the service life of a product is prolonged, and the long-time competitiveness of the product is increased.

As shown in fig. 4, in an embodiment of the present application, a nut 30 is disposed on the connecting plate 212, a screw 40 is sequentially threaded through the structural member 11 and the connecting plate 212 and screwed into the nut 30, so as to fixedly connect the connecting plate 212 with the structural member 11, and the nut 30 is fixed on the connecting plate 212 by welding. In another embodiment of the present application, a threaded hole is formed in the connecting plate 212, and the screw 40 is screwed into the threaded hole of the connecting plate 212 after passing through the sidewall of the structural member 11, so as to fixedly connect the connecting plate 212 with the structural member 11.

The connecting plate 212 is fixed on the structural member 11 through the screw 40, and the screw 40 connection mode has the advantages of simple structure, easy installation, convenient disassembly, simple operation, reliable connection and the like. In addition, the nut 30 is arranged, so that the length of the screw between the screw 40 and the connecting plate 212 is increased, the connecting strength between the connecting plate 212 and the structural member 11 is ensured, the impact resistance of the guide assembly 20 is further improved, the connection reliability between the fixing part 21 and the structural member 11 is further ensured, the probability of separation between the fixing part 21 and the structural member 11 is reduced, the service life of a product is prolonged, and the long-term competitiveness of the product is increased.

As shown in fig. 5, in an embodiment of the present application, the connecting plate 212 is fixed on the structural member 11 by welding, and this connection ensures the connection strength between the fixing portion 21 and the structural member 11, and improves the impact resistance of the guide assembly 20, thereby ensuring the connection reliability between the fixing portion 21 and the structural member 11, reducing the probability of separation between the fixing portion 21 and the structural member 11, prolonging the service life of the product, and increasing the long-term competitiveness of the product.

In one embodiment of the present application, the mounting slot 14 is formed by a recess in the wall of the structural member 11, as shown in figure 5. The installation groove 14 is made by adopting an integral forming process, so that the situation that the structural member 11 is locally thinned due to the fact that a groove is formed by removing materials is avoided, and the overall strength of the structural member 11 is ensured, so that the overall strength of the energy storage rack 100 is ensured, the use reliability of the energy storage rack 100 is improved, the service life of a product is prolonged, and the long-time competitiveness of the product is increased.

As shown in fig. 6, in one embodiment of the present application, a reinforcing rib 213 is disposed between the connection plate 212 and the mounting bracket 211.

The setting of strengthening rib 213 has increased the joint strength between connecting plate 212 and the mounting bracket 211, has reduced the probability of breaking occur between connecting plate 212 and the mounting bracket 211 to the holistic mechanical strength of fixed part 21 has been guaranteed, and then the use reliability of fixed part 21 has been increased. In addition, under the condition that the wall thickness of the fixing part 21 is not increased, the reinforcing ribs 213 effectively increase the strength and rigidity of the fixing part 21, save the material consumption of the fixing part 21, reduce the weight of the fixing part 21 and reduce the product cost.

As shown in fig. 7, the energy storage device provided by the embodiment of the second aspect of the present application includes a plurality of battery plug boxes 200 and the energy storage rack 100, where the battery plug boxes 200 are mounted on the energy storage rack 100. Specifically, the battery compartment 200 is mounted within the mounting cavity 12 of the energy storage rack 100.

The application provides an energy storage equipment, installation intensity is high, shock resistance is good to it is high to have improved energy storage equipment's use reliability, and then has prolonged the life of product, has increased the market competition of product.

In the description of the present application, it is to be noted that the terms "mounted," "connected," and "connected" are to be construed broadly unless otherwise explicitly specified or limited. The term "plurality" means two or more unless explicitly defined otherwise. The specific meaning of the above terms in this application will be understood to be a specific case for those of ordinary skill in the art.

The present application has been described above with reference to preferred embodiments, but these embodiments are merely exemplary and merely illustrative. On the basis of the above, the present application can be subjected to various substitutions and improvements, and the substitutions and the improvements are all within the protection scope of the present application.

Claims (10)

1. An energy storage rack, comprising:

the frame body is a frame structure formed by a plurality of structural members, and mounting holes are formed in part of the structural members; and

a plurality of guide assemblies secured to the structural member and positioned within the mounting apertures, the guide assemblies configured to guide movement of a battery receptacle;

wherein, the guide assembly includes:

the fixing part is positioned in the mounting hole, one end of the fixing part extends out of one side face of the structural part, and the other end of the fixing part is fixedly connected with the other side face of the structural part; and

and the guide part is rotatably arranged on the fixing part and is positioned at one end of the fixing part.

2. Energy storage rack according to claim 1,

the fixing portion includes: the mounting frame is positioned in the mounting hole, one end of the mounting frame extends out of one side face of the structural part, and the other end of the mounting frame is fixedly connected with the other side face of the structural part; and

the connecting plate is arranged at the other end of the mounting frame and is fixedly connected with the structural part.

3. Energy storage rack according to claim 2,

two connecting plates are symmetrically arranged on two sides of the mounting rack.

4. Energy storage rack according to claim 2,

the structural member is provided with an installation groove, and the connecting plate is fixed in the installation groove.

5. Energy storage rack according to claim 4,

the mounting groove is formed by the wall surface of the structural part in a concave mode.

6. Energy storage rack according to claim 2,

and a reinforcing rib is arranged between the connecting plate and the mounting rack.

7. Energy storage rack according to claim 2,

and a nut is arranged on the connecting plate, and a screw sequentially penetrates through the structural member and the connecting plate and is screwed into the nut to fixedly connect the connecting plate with the structural member.

8. Energy storage rack according to one of the claims 1 to 7,

the structural part comprises a vertical upright post and a horizontal beam, and the guide assembly is arranged on the upright post.

9. Energy storage rack according to one of the claims 1 to 7,

a plurality of the guide assemblies are arranged on the two structural members in pairs.

10. An energy storage device comprising a plurality of battery pods and an energy storage rack as claimed in any one of claims 1 to 9, the battery pods being mounted within the energy storage rack.

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