CN218705579U - Energy storage container framework - Google Patents

Abstract

The utility model discloses an energy storage container skeleton belongs to container technical field, and this energy storage container skeleton includes: the base frame comprises two H-shaped channel steels which are arranged in parallel, the two H-shaped channel steels are arranged in parallel, and a plurality of first cross beams are arranged between the two H-shaped channel steels in a crossing manner; the top frame comprises two top side beams which are arranged in parallel, the two top side beams are arranged in parallel, and a plurality of second cross beams are arranged between the two top side beams in a crossing manner; the closed ring assembly is arranged between the bottom frame and the top frame, the upper end of the closed ring assembly is connected with the top frame, the lower end of the closed ring assembly is connected with the bottom frame, and the closed ring assembly is in a closed frame shape. From this, energy storage container skeleton texture can strengthen the structural strength of container skeleton, also reduces stress concentration's problem simultaneously, also can guarantee the continuity of power flow transmission, has avoided the deformation and the fracture scheduling problem of transportation and hoist and mount in-process container.

Description

Energy storage container framework

Technical Field

The utility model belongs to the technical field of the container technique and specifically relates to an energy storage container skeleton is related to.

Background

The energy storage container is an integrated energy storage system developed according to the requirements of a mobile energy storage market, a battery cabinet, a battery management system and a container dynamic loop monitoring system are integrated in the energy storage container, and an energy storage converter and an energy management system can be integrated according to the requirements of customers. With the development of new energy industry, the requirements on the strength and structural stability of the framework of the energy storage container are higher and higher.

At present, the strength stability of the box body is usually enhanced through the integral full-welding of the container framework, but the method not only increases the labor cost, but also solves the problem of stress concentration under the condition of uneven manual full-welding, the stress is applied to a certain area for a long time, so that the area is deformed and cracked, and particularly, the damage of stress concentration can be reflected when the container is hoisted and transported.

SUMMERY OF THE UTILITY MODEL

The utility model discloses an at least solve one of the technical problem who exists among the prior art, for this reason, the utility model provides an energy storage container skeleton can strengthen the structural strength of container skeleton, also reduces stress concentration's problem simultaneously.

According to the utility model discloses energy storage container skeleton, include: the base frame comprises two H-shaped channel steels which are arranged in parallel, the two H-shaped channel steels are arranged in parallel, and a plurality of first cross beams are arranged between the two H-shaped channel steels in a crossing manner; the top frame comprises two top side beams which are arranged in parallel, the two top side beams are arranged in parallel, and a plurality of second cross beams are arranged between the two top side beams in a crossing manner; the closed ring assembly is arranged between the bottom frame and the top frame, the upper end of the closed ring assembly is connected with the top frame, the lower end of the closed ring assembly is connected with the bottom frame, and the closed ring assembly is in a closed frame shape.

According to the utility model discloses energy storage container skeleton has following beneficial effect at least: through setting up the closed ring subassembly, directly transmit the stress that energy storage container skeleton received in transportation, installation to each component part of skeleton on, reduce the moment of flexure and the moment of torsion that the skeleton received, guarantee the continuity of power flow transmission. From this, energy storage container skeleton texture can strengthen the structural strength of container skeleton, also reduces stress concentration's problem simultaneously, also can guarantee the continuity of power flow delivery, has avoided the deformation and the fracture scheduling problem of transportation and hoist and mount in-process container.

According to some embodiments of the invention, the closed loop assembly comprises: the solid round pipe is arranged between the two H-shaped channel steels in a spanning mode; the two side upright posts are respectively connected with the two H-shaped channel steels and the two top side beams; the rectangular pipe, the rectangular pipe strides and establishes between two roof side beams, and solid pipe, two side stand and rectangular pipe set up in same vertical plane.

According to some embodiments of the utility model, the closed ring subassembly still includes two lugs, and two lugs are full-welded respectively on the terminal surface about solid pipe.

According to some embodiments of the utility model, both ends are connected with two H type channel bars full weld respectively about solid pipe.

According to the utility model discloses a some embodiments, two side stands are all perpendicular with solid pipe, and the lower extreme of two side stands is full weld respectively on the upper surface of two H type channel-section steels.

According to the utility model discloses a some embodiments, two roof side rails of two side posts difference perpendicular to, the upper end of two side posts is full-welded respectively on the lower surface of two roof side rails.

According to the utility model discloses a some embodiments, two roof side beams of rectangular pipe perpendicular to, both ends are full-welded respectively on the internal surface of two roof side beams about the rectangular pipe.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

The present invention will be further described with reference to the accompanying drawings and examples;

fig. 1 is a schematic structural diagram of an energy storage container framework according to an embodiment of the present invention;

FIG. 2 is a schematic structural view of a cross-section of the closed loop assembly of FIG. 1;

fig. 3 is a front view of fig. 2.

Reference numerals are as follows:

a chassis 100; an H-shaped channel steel 110; a first cross member 120;

a top frame 200; the roof side rails 210; a second cross member 220;

a closure ring assembly 300; a solid circular tube 310; a side post 320; a rectangular tube 330; a lifting lug 340.

Detailed Description

This section will describe in detail the embodiments of the present invention, preferred embodiments of the present invention are shown in the attached drawings, which are used to supplement the description of the text part of the specification with figures, so that one can intuitively and vividly understand each technical feature and the whole technical solution of the present invention, but they cannot be understood as the limitation of the protection scope of the present invention.

In the description of the present invention, it should be understood that the orientation or positional relationship indicated with respect to the orientation description, such as up, down, front, rear, left, right, etc., is based on the orientation or positional relationship shown in the drawings, and is only for convenience of description and simplification of description, and does not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, a plurality of means are one or more, a plurality of means are two or more, and the terms greater than, less than, exceeding, etc. are understood as not including the number, and the terms greater than, less than, within, etc. are understood as including the number. If the first and second are described for the purpose of distinguishing technical features, they are not to be understood as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

An energy storage container skeleton according to an embodiment of the invention is described with reference to fig. 1 to 3.

As shown in fig. 1 to fig. 3, the utility model discloses energy storage container skeleton of embodiment includes: the chassis 100 comprises two H-shaped channel steels 110 which are arranged in parallel, wherein the two H-shaped channel steels 110 are arranged in parallel, and a plurality of first cross beams 120 are arranged between the two H-shaped channel steels 110 in a crossing manner; the top frame 200 comprises two top side beams 210 which are arranged in parallel, the two top side beams 210 are arranged in parallel, and a plurality of second cross beams 220 are arranged between the two top side beams 210 in a crossing manner; the sealing ring assembly 300 is arranged between the bottom frame 100 and the top frame 200, the upper end of the sealing ring assembly 300 is connected with the top frame 200, the lower end of the sealing ring assembly 300 is connected with the bottom frame 100, and the sealing ring assembly 300 is in a closed frame shape.

As shown in fig. 1, two H-shaped channel steels 110 are all arranged along the front-back direction, a plurality of first beams 120 are uniformly distributed between the two H-shaped channel steels 110, two top side beams 210 are all arranged along the front-back direction, a plurality of second beams 220 are uniformly distributed between the two top side beams 210, the two H-shaped channel steels 110 and the two top side beams 210 are in rectangular distribution, the underframe 100 is parallel to the top frame 200, a plurality of closed ring assemblies 300 are arranged between the underframe 100 and the top frame 200, the closed ring assemblies 300 are all perpendicular to the underframe 100 and the top frame 200, the underframe 100, the top frame 200 and the closed ring assemblies 300 are jointly spliced into a cuboid container framework.

As shown in fig. 2, the closed-loop assembly 300 includes a solid circular tube 310, two side pillars 320, and a rectangular tube 330, the solid circular tube 310 spans between the two H-shaped channel steels 110, the two side pillars 320 connect the two H-shaped channel steels 110 and the two top side beams 210, the rectangular tube 330 spans between the two top side beams 210, and the solid circular tube 310, the two side pillars 320, and the rectangular tube 330 are all located in a plane perpendicular to the H-shaped channel steels 110. The seal ring assembly 300 further comprises two lifting lugs 340, and the two lifting lugs 340 are respectively and fully welded on the left end surface and the right end surface of the solid circular tube 310.

From this, when hoist and mount and transportation container, the lifting hook is connected with two lugs 340 and is lifted by crane the container, two lugs 340 that are located the container bottom all can receive an ascending power, the ascending power that two lugs 340 received can be transmitted to the rectangular pipe 330 on top through two side stand columns 320 on, make solid pipe 310, two side stand columns 320 and rectangular pipe 330 all receive the effect of power, avoid concentrating at the junction stress of two side stand columns 320 and two roof side beams 210, improve the bulk strength of this energy storage container skeleton.

In some embodiments of the present invention, the left and right ends of the solid circular tube 310 are respectively connected to the two H-shaped channel steels 110 by full welding. The two side columns 320 are both perpendicular to the solid circular tube 310, and the lower ends of the two side columns 320 are respectively and fully welded on the upper surfaces of the two H-shaped channel steels 110. The two side pillars 320 are perpendicular to the two top side members 210, respectively, and upper ends of the two side pillars 320 are fully welded to lower surfaces of the two top side members 210, respectively. The rectangular tube 330 is perpendicular to the two top side members 210, and the left and right ends of the rectangular tube 330 are respectively welded to the inner surfaces of the two top side members 210.

As shown in fig. 2 and 3, the left and right sides of the solid circular tube 310 respectively penetrate through the two H-shaped channel steels 110 and cross over the bottom of the frame, at this time, the solid circular tube 310 is fully welded on the H-shaped channel steels 110 on the two sides, and then the lifting lugs 340 on the two sides are fully welded on the end surfaces of the solid circular tube 310 respectively. The lower end faces of the two side columns 320 are perpendicular to the solid circular tube 310 and are placed on the upper surface of the H-shaped channel steel 110, the end faces of the circular tube 310 are Ji Shixin on the outer side faces of the side columns 320, and then the two side columns 320 are fully welded on the surface of the H-shaped channel steel 110. The upper end surfaces of the side pillars 320 are vertically aligned with the lower surfaces of the side roof rails 210 on both sides, and the upper end surfaces of the side pillars 320 are fully welded to the lower surfaces of the side roof rails 210 on both sides. Two end faces of a rectangular pipe 330 and two side upright posts 320 are perpendicular to the inner surfaces of the two top side beams 210 and are aligned to the upper end face positions of the two side upright posts 320, the rectangular pipe 330 is fully welded on the inner surfaces of the two top side beams 210, the solid circular pipe 310, the side upright posts 320 and the rectangular pipe 330 are strictly aligned and are positioned in the same vertical plane to form a closed ring assembly 300, and the closed ring assembly 300 is perpendicular to the two H-shaped channel steels 110 and the two top side beams 210.

In conclusion, through setting up closed ring subassembly 300, directly transmit the stress that energy storage container skeleton received in transportation, the installation on each component part of skeleton, reduce the moment of flexure and the moment of torsion that the skeleton received, guarantee the continuity of power flow transmission. From this, energy storage container skeleton texture can strengthen the structural strength of container skeleton, also reduces stress concentration's problem simultaneously, also can guarantee the continuity of power flow delivery, has avoided the deformation and the fracture scheduling problem of transportation and hoist and mount in-process container.

The embodiments of the present invention have been described in detail with reference to the drawings, but the present invention is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present invention within the knowledge of those skilled in the art.

Claims (7)

1. An energy storage container frame, comprising:

the base frame (100) comprises two H-shaped channel steels (110) which are arranged in parallel, the two H-shaped channel steels (110) are arranged in parallel, and a plurality of first cross beams (120) are arranged between the two H-shaped channel steels (110) in a crossing manner;

the top frame (200) comprises two top side beams (210) which are arranged in parallel, the two top side beams (210) are arranged in parallel, and a plurality of second cross beams (220) are arranged between the two top side beams (210) in a crossing manner;

the sealing ring assembly comprises a plurality of sealing ring assemblies (300), the sealing ring assemblies (300) are arranged between the bottom frame (100) and the top frame (200), the upper ends of the sealing ring assemblies (300) are connected with the top frame (200), the lower ends of the sealing ring assemblies (300) are connected with the bottom frame (100), and the sealing ring assemblies (300) are in a closed frame shape.

2. The energy storage container skeleton of claim 1, wherein the closed ring assembly (300) comprises:

the solid round pipe (310), the solid round pipe (310) spans between the two H-shaped channel steels (110);

the two side columns (320), the two side columns (320) are respectively connected with the two H-shaped channel steels (110) and the two top side beams (210);

the solid circular tube (310), the two side columns (320) and the rectangular tube (330) are arranged in the same vertical plane.

3. The energy storage container framework of claim 2, wherein the closed ring assembly (300) further comprises two lifting lugs (340), and the two lifting lugs (340) are respectively and fully welded on the left and right end faces of the solid circular tube (310).

4. The energy storage container framework of claim 3, wherein the left end and the right end of the solid circular tube (310) are respectively in full-welding connection with the two H-shaped channel steels (110).

5. The energy storage container framework of claim 4, wherein the two side columns (320) are perpendicular to the solid circular tube (310), and the lower ends of the two side columns (320) are respectively and fully welded on the upper surfaces of the two H-shaped channel steels (110).

6. The energy storage container framework of claim 5, wherein the two side columns (320) are perpendicular to the two top side beams (210), and the upper ends of the two side columns (320) are fully welded to the lower surfaces of the two top side beams (210).

7. The energy storage container framework of claim 6, wherein the rectangular tube (330) is perpendicular to the two top side beams (210), and left and right ends of the rectangular tube (330) are respectively welded on inner surfaces of the two top side beams (210).

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