CN114132643A

CN114132643A - Energy storage container shell manufactured by adopting 3D printing technology

Info

Publication number: CN114132643A
Application number: CN202111442671.XA
Authority: CN
Inventors: 李庆生; 陶以彬; 陈巨龙; 蔡德龙; 龙家焕; 王德顺; 孙斌; 李官军; 张裕; 余豪杰; 薛毅; 王开毅; 李震; 姜守德; 张兆丰; 李晓亮; 邓朴; 戴振洲; 唐学用
Original assignee: Guizhou Power Grid Co Ltd
Current assignee: Guizhou Power Grid Co Ltd
Priority date: 2021-11-30
Filing date: 2021-11-30
Publication date: 2022-03-04
Anticipated expiration: 2041-11-30
Also published as: CN114132643B

Abstract

The invention discloses an energy storage container shell manufactured by adopting a 3D printing technology, which comprises a box body, wherein the box body is manufactured by adopting 3D printing, and cavities are formed in two sides of the bottom of the box body; the displacement assembly comprises a rotating piece and a displacement piece, the displacement piece is connected with the rotating piece and moves along with the rotation of the rotating piece, and the displacement assembly is arranged in the cavity; the supporting component is arranged outside the box body, and the displacement piece penetrates out of the cavity and is connected with the supporting component. According to the invention, the support assembly arranged outside the box body is used for limiting and reinforcing the low position of the box body, the flexible adjustment of the position and the supporting point of the support assembly is realized through the displacement assembly, the shaking, the inclination and even the side turning in the transportation process due to the higher integral gravity center of the container are prevented, and the safe transportation of the container is ensured.

Description

Energy storage container shell manufactured by adopting 3D printing technology

Technical Field

The invention relates to the technical field of containers, in particular to an energy storage container shell manufactured by adopting a 3D printing technology.

Background

China's companies that manufacture containers on a large scale mainly manufacture shipping containers, and special customized services cannot be provided for small-batch products in the power industry. The conventional companies for receiving the container customized service in the power industry are small in scale, and the capacity and the delivery date are difficult to meet the requirements of the future energy storage industry.

The most time-consuming process in the production process of the container is the manufacture of a container frame, and the container frame comprises a channel steel base, a stand column, a top cross beam and the like. All the parts can be manufactured by a 3D printing technology, and compared with the traditional processing means, the 3D printing technology has the advantages of high speed, labor and field saving, high customization degree, high material utilization rate and the like. However, the 3D printed container is still slightly insufficient in strength and needs to be enhanced in stability.

Disclosure of Invention

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. In this section, as well as in the abstract and the title of the invention of this application, simplifications or omissions may be made to avoid obscuring the purpose of the section, the abstract and the title, and such simplifications or omissions are not intended to limit the scope of the invention.

In order to solve the technical problems, the invention provides the following technical scheme: an energy storage container shell manufactured by adopting a 3D printing technology comprises a box body, wherein the box body is manufactured by 3D printing, and cavities are formed in two sides of the bottom of the box body; the displacement assembly comprises a rotating piece and a displacement piece, the displacement piece is connected with the rotating piece and moves along with the rotation of the rotating piece, and the displacement assembly is arranged in the cavity; the supporting component is arranged outside the box body, and the displacement piece penetrates out of the cavity and is connected with the supporting component.

As a preferable scheme of the energy storage container shell manufactured by adopting the 3D printing technology, the invention comprises: the rotating part comprises a rotating hand wheel and a first bevel gear, the rotating hand wheel is connected with the first bevel gear, and the rotating hand wheel extends to the outside of the box body from the cavity.

As a preferable scheme of the energy storage container shell manufactured by adopting the 3D printing technology, the invention comprises: the rotating part further comprises a second bevel gear and a rotating screw rod, the second bevel gear is meshed with the first bevel gear and is connected with the rotating screw rod, and one end, far away from the second bevel gear, of the rotating screw rod is connected with the inner wall of the cavity.

As a preferable scheme of the energy storage container shell manufactured by adopting the 3D printing technology, the invention comprises: the displacement piece including set up in the displacement bolt in the rotation screw rod outside, the displacement bolted connection has the telescopic link, the telescopic link is connected with the sliding block, the sliding block through extend to the outside connecting rod of cavity with the supporting component is connected.

As a preferable scheme of the energy storage container shell manufactured by adopting the 3D printing technology, the invention comprises: the telescopic link includes outer pole and interior pole, outer pole with displacement bolted connection, interior pole cover locate the outer pole inside, and with the sliding block is connected.

As a preferable scheme of the energy storage container shell manufactured by adopting the 3D printing technology, the invention comprises: the top and the bottom of the sliding block are both provided with an oblique block.

As a preferable scheme of the energy storage container shell manufactured by adopting the 3D printing technology, the invention comprises: the cavity includes holding chamber and displacement chamber, rotate the piece and be located the holding intracavity, the displacement piece is located the displacement intracavity, and displacement chamber top and bottom all are provided with the slant groove of sliding, and the slant groove of sliding extends to the holding chamber from the displacement chamber slope, the slant piece is located the slant inslot that slides.

As a preferable scheme of the energy storage container shell manufactured by adopting the 3D printing technology, the invention comprises: the supporting component comprises a base, a vertical rod and a supporting rod, the supporting rod is connected with the base in a rotating mode, a clamping groove is formed in the vertical rod, and one end, far away from the base, of the supporting rod is located in the clamping groove.

As a preferable scheme of the energy storage container shell manufactured by adopting the 3D printing technology, the invention comprises: the base includes fixing base and telescopic adjusting rod, telescopic adjusting rod is located inside the fixing base, the connecting rod passes the fixing base and is connected with telescopic adjusting rod, the bracing piece rotates to be connected in telescopic adjusting rod tip.

As a preferable scheme of the energy storage container shell manufactured by adopting the 3D printing technology, the invention comprises: the vertical rod is rotatably connected with the base, a notch is formed in the bottom of the clamping groove, and a clamping groove is formed in the top of the vertical rod.

The invention has the beneficial effects that: according to the invention, the support assembly arranged outside the box body is used for limiting and reinforcing the low position of the box body, the flexible adjustment of the position and the supporting point of the support assembly is realized through the displacement assembly, the shaking, the inclination and even the side turning in the transportation process due to the higher integral gravity center of the container are prevented, and the safe transportation of the container is ensured.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise. Wherein:

fig. 1 is a schematic view of the overall structure of the present invention.

FIG. 2 is a schematic view of the displacement assembly-support assembly connection of the present invention.

FIG. 3 is a schematic diagram of the internal structure of the cavity of the present invention.

Fig. 4 is a schematic structural view of the displacement member of the present invention.

FIG. 5 is a schematic view of a support assembly according to the present invention.

FIG. 6 is an enlarged view of A in FIG. 3 according to the present invention.

Fig. 7 is a schematic view of the support assembly of the present invention folded.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those specifically described herein, and it will be apparent to those of ordinary skill in the art that the present invention may be practiced without departing from the spirit and scope of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.

Furthermore, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 and 7, a first embodiment of the present invention provides an energy storage container housing manufactured by using a 3D printing technology, which includes a container body 100, a displacement assembly 200 and a support assembly 300, wherein the container body 100 is manufactured by using 3D printing, and cavities 101 are formed at two sides of the bottom of the container body 100; the displacement assembly 200 is used for adjusting the external supporting assembly 300 to a proper position of the box body 100 so as to better play an auxiliary supporting effect on the box body 100, and comprises a rotating piece 201 and a displacement piece 202, wherein the displacement piece 202 is connected with the rotating piece 201 and moves along with the rotation of the rotating piece 201, when the rotating piece 201 is rotated, the displacement piece 202 moves along the rotating piece 201 along with the rotation of the rotating piece 201 so as to drive the supporting assembly 300 to move, and the displacement assembly 200 is arranged in the cavity 101; the supporting component 300 is arranged outside the container body 100, the displacement piece 202 penetrates out of the cavity 101 to be connected with the supporting component 300, the supporting component 300 is used for limiting and reinforcing the low position of the container body 100, the situation that the container is rocked, inclined or even turned on one side due to the fact that the whole gravity center of the container is high in the transportation process is avoided, and safe transportation of the container is guaranteed.

Further, the rotating member 201 includes a rotating hand wheel 201a and a first bevel gear 201b, the rotating hand wheel 201a is connected to the first bevel gear 201b, and the rotating hand wheel 201a extends from the cavity 101 to the outside of the box 100. The rotating member 201 further comprises a second bevel gear 201c and a rotating screw 201d, the second bevel gear 201c is engaged with the first bevel gear 201b, the second bevel gear 201c is connected with the rotating screw 201d, and one end of the rotating screw 201d far away from the second bevel gear 201c is connected with the inner wall of the cavity 101.

The rotating hand wheel 201a is located outside the box body 100, when the supporting assembly 300 is needed to support the box body 100 in an auxiliary mode, the rotating hand wheel 201a is rotated, the rotating hand wheel 201a rotates to drive the first bevel gear 201b to rotate, the first bevel gear 201b rotates to drive the second bevel gear 201c meshed with the first bevel gear 201b to rotate, the second bevel gear 201c rotates to drive the rotating screw 201d connected with the second bevel gear 201c to rotate, one end, far away from the second bevel gear 201c, of the rotating screw 201d is connected with the inner wall of the cavity 101, and the rotating screw 201d is connected with the inner wall of the cavity 101 through a rotating shaft.

Further, the displacement member 202 comprises a displacement bolt 202a disposed outside the rotating screw 201d, the displacement bolt 202a is connected with a telescopic rod 202b, the telescopic rod 202b is connected with a sliding block 202c, and the sliding block 202c is connected with the support assembly 300 through a connecting rod 202d extending to the outside of the cavity 101.

When the rotating screw 201d rotates, the displacement bolt 202a arranged on the outer side of the rotating screw 201d displaces along the rotating screw 201d, the displacement bolt 202a displaces and simultaneously drives the telescopic rod 202b to displace, and the telescopic rod 202b moves to drive the sliding block 202c and the connecting rod 202d to move, so that the supporting component 300 is finally driven to move, and the position of the supporting component 300 is adjusted by rotating the rotating hand wheel 201 a.

Further, the telescopic rod 202b comprises an outer rod 202b-1 and an inner rod 202b-2, the outer rod 202b-1 is connected with the displacement bolt 202a, and the inner rod 202b-2 is sleeved inside the outer rod 202b-1 and connected with the sliding block 202 c. The top and the bottom of the sliding block 202c are provided with oblique blocks 202 c-1. The cavity 101 comprises an accommodating cavity 101a and a displacement cavity 101b, the rotating part 201 is located in the accommodating cavity 101a, the displacement part 202 is located in the displacement cavity 101b, oblique sliding grooves 101c are formed in the top and the bottom of the displacement cavity 101b, the oblique sliding grooves 101c extend from the displacement cavity 101b to the accommodating cavity 101a in an inclined mode, and the oblique blocks 202c-1 are located in the oblique sliding grooves 101 c.

When the rotating hand wheel 201a is rotated to drive the displacement member 202 to move along the rotating screw 201d, if the displacement member 202 moves towards the middle position of the box body 100 along the rotating screw 201d, the inclined block 202c-1 arranged on the sliding block 202c moves towards the direction far away from the accommodating cavity 101a along the inclined sliding groove 101c, the inner rod 202b-2 gradually extends out of the outer rod 202b-1 along with the movement of the sliding block 202c, and the length of the telescopic rod 202b is increased; if the displacement member 202 moves towards the two ends of the box body along the rotating screw 201d, the inclined block 202c-1 of the sliding block 202c moves towards the direction close to the accommodating cavity 101a along the inclined sliding groove 101c, the inner rod 202b-2 gradually enters the inner part of the outer rod 202b-1 along with the movement of the sliding block 202c, and the length of the telescopic rod 202b is reduced.

Further, the supporting component 300 comprises a base 301, a vertical rod 302 and a supporting rod 303, the supporting rod 303 is rotatably connected with the base 301, a clamping groove 302a is formed in the vertical rod 302, and one end, far away from the base 301, of the supporting rod 303 is located in the clamping groove 302 a. The base 301 comprises a fixed seat 301a and a telescopic adjusting rod 301b, the telescopic adjusting rod 301b is located inside the fixed seat 301a, the connecting rod 202d penetrates through the fixed seat 301a to be connected with the telescopic adjusting rod 301b, and the supporting rod 303 is rotatably connected to the end of the telescopic adjusting rod 301 b.

The base 301, the vertical rods 302 and the support rods 303 form a triangular support for the box body 100, so that the best supporting and protecting effect on the box body 100 is achieved. When the displacement member 202 moves towards the middle of the box 100 along the rotating screw 201d, the inclined block 202c-1 of the sliding block 202c moves towards the direction far away from the accommodating cavity 101a along the inclined sliding groove 101c, the inner rod 202b-2 gradually extends out of the outer rod 202b-1 along with the movement of the sliding block 202c, and the length of the telescopic rod 202b increases, the support assembly 300 generally moves towards the middle of the box 100 along with the displacement member 202c, and meanwhile, the connecting rod 202d connected with the telescopic adjusting rod 301b inside the fixed seat 301a gradually extends out of the displacement cavity 101b along with the increase of the length of the telescopic rod 202b, so as to drive the telescopic adjusting rod 301b inside the fixed seat 301a to gradually extend out, the telescopic adjusting rod 301b moves towards the direction far away from the box 100, the bottom edge of the triangle increases, and the supporting rod 303 rotatably connected with the telescopic adjusting rod 301b gradually moves downwards along the clamping groove 302a formed in the vertical rod 302, the supporting point of the supporting member 300 is also moved down;

when the displacement member 202 moves towards the two ends of the box 100 along the rotating screw 201d, the inclined block 202c-1 of the sliding block 202c moves towards the direction close to the accommodating cavity 101a along the inclined sliding groove 101c, the inner rod 202b-2 gradually enters the inner part of the outer rod 202b-1 along with the movement of the sliding block 202c, and the length of the telescopic rod 202b decreases, the support assembly 300 generally moves towards the two ends of the box 100 along with the displacement member 202c, and meanwhile, the connecting rod 202d connected with the telescopic adjusting rod 301b inside the fixed seat 301a gradually moves towards the accommodating cavity 101a along with the decrease of the length of the telescopic rod 202b, so as to drive the telescopic adjusting rod 301b inside the fixed seat 301a to gradually move towards the inside of the fixed seat 301a, the telescopic adjusting rod 301b moves towards the direction close to the box 100, the bottom side of the triangle decreases, and the supporting rod 303 rotatably connected with the telescopic adjusting rod 301b gradually moves upwards along the clamping groove 302a formed by the vertical rod 302, the support point of the support assembly 300 is also moved upward.

The overall displacement of the supporting component 300 and the change of the supporting point of the supporting component 300 are simultaneously realized by rotating the rotating handwheel 201a, so that the operator can effectively protect the box body 100. Along with the movement of the supporting component 300 to the two ends of the box body 100 along with the displacement piece 202, the supporting rod 303 connected with the telescopic adjusting rod 301b in a rotating mode gradually moves upwards along the clamping groove 302a formed in the vertical rod 302, the supporting center also moves upwards along with the supporting rod, better and better supporting effect can be achieved for the box body 100, meanwhile, the lengths of the telescopic rod 202b and the telescopic adjusting rod 301b are synchronously shortened, the bottom side stress moment of triangular support can be reduced, and better supporting effect is achieved.

When the box 100 receives an inclination force, the supporting force of the supporting component 300 mainly comes from the supporting rod 303, the stress of the supporting rod 300 is transmitted to the base 301, the force in the vertical direction acts on the ground when the base 301 decomposes the force, the force in the horizontal direction acts on the sliding block 202c and the inclined block 202c-1, and when the inclined block 202c-1 moves towards the direction close to the accommodating cavity 101a along the inclined sliding groove 101c, namely, the stress point of the sliding block 202c gradually moves towards the middle position of the box 100, so that a more stable supporting effect can be achieved.

Further, the vertical rod 302 is rotatably connected with the base 301, a notch 302b is formed in the bottom of the clamping groove 302a, and a clamping groove 302c is formed in the top of the vertical rod 302. When the supporting component 300 is not needed to be used, the supporting component 300 is moved to a position close to the middle of the box body 100 through rotating the hand wheel 201a, the end of the supporting rod 303 reaches the notch 302b at the bottom of the clamping groove 302a at the moment, the hand wheel 201a is continuously rotated to move the supporting component 300 to the middle of the box body 100, the supporting rod 303 is taken out from the notch 302b, the length of the telescopic rod 202b and the length of the telescopic adjusting rod 301b reach the longest length at the moment, then the base 301 is rotated upwards, the supporting rod 303 is placed in the accommodating groove in the middle of the base 301, the end of the telescopic adjusting rod 301b is clamped in the clamping groove 302c at the top of the vertical rod 302, the supporting component 300 can be folded and placed, and the size of the supporting component 300 under the condition of not being used is reduced.

It should be noted that the above-mentioned embodiments are only for illustrating the technical solutions of the present invention and not for limiting, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the claims of the present invention.

Claims

1. The utility model provides an adopt energy storage container shell that 3D printing technology made which characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

the box body (100) is manufactured by 3D printing, and cavities (101) are formed in two sides of the bottom of the box body (100);

the displacement assembly (200) comprises a rotating piece (201) and a displacement piece (202), the displacement piece (202) is connected with the rotating piece (201) and moves along with the rotation of the rotating piece (201), and the displacement assembly (200) is arranged in the cavity (101);

the supporting component (300) is arranged outside the box body (100), and the displacement piece (202) penetrates out of the cavity (101) and is connected with the supporting component (300).

2. An energy storage container housing made using 3D printing technology as claimed in claim 1 wherein: the rotating piece (201) comprises a rotating hand wheel (201a) and a first bevel gear (201b), the rotating hand wheel (201a) is connected with the first bevel gear (201b), and the rotating hand wheel (201a) extends from the cavity (101) to the outside of the box body (100).

3. An energy storage container housing made using 3D printing technology as claimed in claim 2 wherein: the rotating part (201) further comprises a second bevel gear (201c) and a rotating screw (201d), the second bevel gear (201c) is meshed with the first bevel gear (201b), the second bevel gear (201c) is connected with the rotating screw (201d), and one end, far away from the second bevel gear (201c), of the rotating screw (201d) is connected with the inner wall of the cavity (101).

4. An energy storage container housing made using 3D printing technology as claimed in claim 3 wherein: the displacement piece (202) comprises a displacement bolt (202a) arranged on the outer side of the rotating screw rod (201d), the displacement bolt (202a) is connected with an expansion rod (202b), the expansion rod (202b) is connected with a sliding block (202c), and the sliding block (202c) is connected with the supporting component (300) through a connecting rod (202d) extending to the outside of the cavity (101).

5. An energy storage container housing made using 3D printing technology as claimed in claim 4 wherein: the telescopic rod (202b) comprises an outer rod (202b-1) and an inner rod (202b-2), the outer rod (202b-1) is connected with the displacement bolt (202a), and the inner rod (202b-2) is sleeved inside the outer rod (202b-1) and connected with the sliding block (202 c).

6. An energy storage container housing made using 3D printing technology as claimed in claim 5 wherein: the top and the bottom of the sliding block (202c) are provided with oblique blocks (202 c-1).

7. An energy storage container housing made using 3D printing technology as claimed in claim 6 wherein: the cavity (101) comprises an accommodating cavity (101a) and a displacement cavity (101b), the rotating piece (201) is located in the accommodating cavity (101a), the displacement piece (202) is located in the displacement cavity (101b), the top and the bottom of the displacement cavity (101b) are respectively provided with an oblique sliding groove (101c), the oblique sliding groove (101c) extends from the displacement cavity (101b) to the accommodating cavity (101a) in an inclined mode, and the oblique block (202c-1) is located in the oblique sliding groove (101 c).

8. An energy storage container casing manufactured using 3D printing technology according to any of claims 4-7, characterised in that: support assembly (300) include base (301), vertical pole (302) and bracing piece (303), bracing piece (303) rotate with base (301) and are connected, have seted up joint groove (302a) on vertical pole (302), and the one end that base (301) were kept away from in bracing piece (303) is located joint groove (302 a).

9. An energy storage container housing made using 3D printing technology as claimed in claim 8 wherein: base (301) are including fixing base (301a) and telescopic adjusting pole (301b), telescopic adjusting pole (301b) are located inside fixing base (301a), connecting rod (202d) pass fixing base (301a) and are connected with telescopic adjusting pole (301b), bracing piece (303) rotate to be connected in telescopic adjusting pole (301b) tip.

10. An energy storage container housing made using 3D printing technology as claimed in claim 9 wherein: vertical pole (302) rotate with base (301) and are connected, joint groove (302a) bottom is provided with breach (302b), vertical pole (302) top is provided with draw-in groove (302 c).