CN221709007U - Energy storage equipment - Google Patents

Abstract

The utility model discloses an energy storage device, including: an energy storage box and a pulley; the bottom of the energy storage box is connected to a pulley, the side of the energy storage box is connected to an interface, the side of the energy storage box is connected to a protective mechanism, and the top of the energy storage box is connected to a moving mechanism. The energy storage device can drive a threaded rod to dock with a thread groove, at which time the threaded rod can be rotated, and the threaded rod can slide through the thread groove when it rotates, and when the threaded rod completely slides into the thread groove, the protective cover can be fixed, and after the protective cover is fixed, the interface can be protected, the second adjustment rod can be clamped and fixed, and then the first adjustment rod can be pulled out in the same way, and after the first adjustment rod is pulled out, the connecting handle can be adjusted to a suitable height, and at this time, the first adjustment rod can be pulled to drive the energy storage box to slide through the pulley, so that the energy storage box does not need to bend down to push when moving.

Description

Energy storage device

Technical Field

The utility model relates to the technical field of energy storage, in particular to an energy storage device.

Background Art

Energy storage mainly refers to the storage of electrical energy. Energy storage is also a term in oil reservoirs, representing the ability of reservoirs to store oil and gas. Energy storage itself is not an emerging technology. Energy storage equipment is needed to supply power in the wild or during power outages. Existing energy storage equipment still has certain defects when used, such as;

Energy storage devices can be charged to store electrical energy, and can also be discharged to provide power for external devices. Existing energy storage devices have a hybrid system that supports AC + DC output, so that when charging the DELTAMax and DELTAPro, it can save the loss of AC to DC conversion and directly charge the DELTAMax and DELTAPro with DC. Compared with traditional generators for other outdoor power sources, the charging efficiency is increased by 60%, which effectively improves the oil-to-electricity conversion efficiency, reduces the charging fuel consumption per kilowatt-hour, realizes efficient use of energy, and greatly reduces power loss. The plug interfaces of existing energy storage devices are usually exposed to the outside, which makes it easy for dust to cover the plug interfaces, resulting in poor connection when the connecting cable or socket is plugged into the plug interface, thereby affecting the use of the plug interface and shortening the service life of the energy storage device. The energy storage devices currently on the market do not have a structure to protect the interface, so they need to be improved.

Utility Model Content

The utility model provides the following technical solutions: The purpose of the utility model is to provide an energy storage device to solve the problems raised by the above-mentioned background technology that the energy storage devices currently on the market have many defects when in use, it is inconvenient to protect the interface, and when the energy storage box needs to be moved, it is necessary to bend over to push it, which is quite laborious.

To achieve the above-mentioned purpose, the utility model provides the following technical solutions: an energy storage device, comprising: an energy storage box and a pulley;

The bottom of the energy storage box is connected to a pulley, the side of the energy storage box is connected to an interface, the side of the energy storage box is connected to a protective mechanism, and the top of the energy storage box is connected to a moving mechanism.

Preferably, the protective mechanism comprises a hinge, a protective cover, a sliding groove, a threaded rod and a threaded groove;

The side of the energy storage box is connected with a hinge.

Preferably, a protective cover is connected to the side of the hinge, and a sliding groove is provided through the inside of the protective cover.

Preferably, a threaded rod is slidably connected inside the sliding groove, and a threaded groove is provided on the side of the energy storage box.

Preferably, the moving mechanism includes a slide groove, a first adjusting rod, a second adjusting rod, a limit groove, a limit block, an extrusion groove, a steel ball, a spring, a connecting handle and a snap groove;

A first adjusting rod is arranged on the top of the energy storage box, a second adjusting rod is embedded inside the first adjusting rod, and a connecting handle is connected to the top of the second adjusting rod;

The energy storage box and the end of the first adjusting rod are both provided with sliding grooves.

Preferably, a limiting groove is provided on the inner wall of the slide groove, and a locking groove is provided on the inner wall of the limiting groove.

Preferably, both sides of the first adjusting rod and the second adjusting rod are connected with limiting blocks, and the side surfaces of the limiting blocks are provided with extrusion grooves.

Preferably, a spring is connected inside the extrusion groove, and a steel ball is connected to one end of the spring.

Compared with the prior art, the beneficial effects of the utility model are: the energy storage device can drive the threaded rod to dock with the threaded groove, at which time the threaded rod can be rotated, and the threaded rod can slide through the threaded groove when it rotates, and when the threaded rod completely slides into the threaded groove, the protective cover can be fixed, and after the protective cover is fixed, the interface can be protected, the second adjusting rod can be snap-fitted and fixed, and then the first adjusting rod can be pulled out in the same way, and after the first adjusting rod is pulled out, the connecting handle can be adjusted to a suitable height, and at this time the first adjusting rod can be pulled to drive the energy storage box to slide through the pulley, so that the energy storage box does not need to bend over to push when moving.

1. When the energy storage box is not needed, the protective cover can be pulled to rotate through the hinge. When the protective cover rotates to the side of the interface, the threaded rod can be pushed to slide through the sliding groove. When the threaded rod slides to the side of the energy storage box, the threaded rod can be driven to dock with the threaded groove. At this time, the threaded rod can be rotated. The threaded rod can slide through the threaded groove. When the threaded rod completely slides into the threaded groove, the protective cover can be fixed. After the protective cover is fixed, the interface can be protected, which is convenient for using the protective cover to protect the interface;

2. When the energy storage box needs to be moved, the connecting handle is pulled to drive the second adjusting rod to slide through the slide groove. When the second adjusting rod slides, it can drive the arc surface of the steel ball to squeeze the engaging groove. When the steel ball is squeezed, it can slide in the extrusion groove. When the steel ball slides, it can squeeze the spring. When the steel ball slides into the inside of the extrusion groove, the limit block can slide on the limit groove. When the limit block slides to the specified position, it can drive the steel ball to slide to the top engaging groove position. At this time, the steel ball can be reset by the elastic force of the spring itself, and the steel ball can be stuck in the engaging groove when reset. When the steel ball is stuck in the engaging groove, the second adjusting rod can be locked and fixed, and then the first adjusting rod can be pulled out in the same way. After the first adjusting rod is pulled out, the connecting handle can be adjusted to a suitable height. At this time, the first adjusting rod can be pulled to drive the energy storage box to slide through the pulley, so that the energy storage box does not need to bend down to push when moving.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a schematic diagram of the front cross-sectional structure of the utility model;

Figure 2 is a side view of the structure of the utility model;

Figure 3 is a schematic diagram of the side cross-sectional structure of the utility model;

FIG4 is an enlarged structural diagram of part A of the utility model;

FIG5 is an enlarged structural diagram of part B of the utility model.

In the figure: 1. energy storage box; 2. pulley; 3. interface; 4. protection mechanism; 401. hinge; 402. protection cover; 403. sliding groove; 404. threaded rod; 405. threaded groove; 5. moving mechanism; 501. sliding groove; 502. first adjusting rod; 503. second adjusting rod; 504. limiting groove; 505. limiting block; 506. extrusion groove; 507. steel ball; 508. spring; 509. connecting handle; 510. locking groove.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the utility model to clearly and completely describe the technical solutions in the embodiments of the utility model. Obviously, the described embodiments are only part of the embodiments of the utility model, not all of the embodiments. Based on the embodiments in the utility model, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the utility model.

Please refer to Figures 1-5, the utility model provides a technical solution: an energy storage device, comprising: an energy storage box 1 and a pulley 2;

A pulley 2 is connected to the bottom of the energy storage box 1, an interface 3 is connected to the side of the energy storage box 1, a protective mechanism 4 is connected to the side of the energy storage box 1, and a moving mechanism 5 is connected to the top of the energy storage box 1.

The protective mechanism 4 includes a hinge 401, a protective cover 402, a sliding groove 403, a threaded rod 404 and a threaded groove 405. The hinge 401 is connected to the side of the energy storage box 1. When the energy storage box 1 is not needed, the protective cover 402 can be pulled to rotate through the hinge 401. When the protective cover 402 is rotated to the side of the interface 3, the threaded rod 404 can be pushed to slide through the sliding groove 403.

A protective cover 402 is connected to the side of the hinge 401 , and a sliding groove 403 is provided inside the protective cover 402 . When the threaded rod 404 slides to the side of the energy storage box 1 , the threaded rod 404 can be driven to dock with the threaded groove 405 .

A threaded rod 404 is slidably connected inside the sliding groove 403, and a threaded groove 405 is opened on the side of the energy storage box 1. At this time, the threaded rod 404 can be rotated, and the threaded rod 404 can slide through the threaded groove 405. When the threaded rod 404 completely slides into the threaded groove 405, the protective cover 402 can be fixed.

The moving mechanism 5 includes a slide groove 501, a first adjusting rod 502, a second adjusting rod 503, a limiting groove 504, a limiting block 505, an extrusion groove 506, a steel ball 507, a spring 508, a connecting handle 509 and a clamping groove 510. The first adjusting rod 502 is arranged on the top of the energy storage box 1, the second adjusting rod 503 is embedded in the first adjusting rod 502, and the top of the second adjusting rod 503 is connected to the connecting handle 509;

The energy storage box 1 and the end of the first adjusting rod 502 are both provided with a slide groove 501 . When the energy storage box 1 needs to be moved, the connecting handle 509 is pulled to drive the second adjusting rod 503 to slide through the slide groove 501 .

The inner wall of the slide groove 501 is provided with a limit groove 504, and the inner wall of the limit groove 504 is provided with a locking groove 510. When the second adjusting rod 503 slides, the arc surface of the steel ball 507 can be driven to squeeze the locking groove 510, and the steel ball 507 can slide in the squeezing groove 506 when being squeezed.

The first adjusting rod 502 and the second adjusting rod 503 are connected to the limiting blocks 505 on both sides. The side of the limiting blocks 505 is provided with extrusion grooves 506. When the steel ball 507 slides, it can squeeze the spring 508. When the steel ball 507 slides into the extrusion groove 506, the limiting blocks 505 can slide on the limiting grooves 504.

A spring 508 is connected inside the extrusion groove 506, and one end of the spring 508 is connected to a steel ball 507. When the limit block 505 slides to the specified position, it can drive the steel ball 507 to slide to the top locking groove 510 position. At this time, the steel ball 507 can be reset by the elastic force of the spring 508 itself.

Working principle: when using the energy storage device, first, when the energy storage box 1 is not needed, the protective cover 402 can be pulled to rotate through the hinge 401, and when the protective cover 402 is rotated to the side of the interface 3, the threaded rod 404 can be pushed to slide through the sliding groove 403, and when the threaded rod 404 slides to the side of the energy storage box 1, the threaded rod 404 can be driven to dock with the threaded groove 405. At this time, the threaded rod 404 can be rotated, and the threaded rod 404 can be rotated to slide through the threaded groove 405. When the threaded rod 404 completely slides into the threaded groove 405, the protective cover 402 can be fixed. After the protective cover 402 is fixed, the interface 3 can be protected. When the energy storage box 1 needs to be moved, the connecting handle 509 is pulled to drive the second adjusting rod 503 to slide through the sliding groove 501. When the second adjusting rod 503 slides, it can drive the arc surface of the steel ball 507 to squeeze the engaging groove 510. When the steel ball 507 is squeezed, it can When the steel ball 507 is inserted into the locking groove 510, the second adjusting rod 503 can be locked and fixed, and then the first adjusting rod 502 can be pulled out in the same way. After the first adjusting rod 502 is pulled out, the connecting handle 509 can be adjusted to a suitable height. At this time, the first adjusting rod 502 can be pulled to drive the energy storage box 1 to slide through the pulley 2, so that the energy storage box 1 does not need to bend down to push when moving. The content not described in detail in this description belongs to the prior art known to professional and technical personnel in this field.

Although the present invention has been described in detail with reference to the aforementioned embodiments, those skilled in the art may still modify the technical solutions described in the aforementioned embodiments, or make equivalent substitutions for some of the technical features therein. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and principles of the present invention shall be included in the protection scope of the present invention.

Claims (8)

1. An energy storage device, comprising: an energy storage box (1) and a pulley (2), characterized in that; The bottom of the energy storage box (1) is connected to a pulley (2), the side of the energy storage box (1) is connected to an interface (3), the side of the energy storage box (1) is connected to a protective mechanism (4), and the top of the energy storage box (1) is connected to a moving mechanism (5). 2. An energy storage device according to claim 1, characterized in that: the protective mechanism (4) comprises a hinge (401), a protective cover (402), a sliding groove (403), a threaded rod (404) and a threaded groove (405); A hinge (401) is connected to the side of the energy storage box (1). 3. An energy storage device according to claim 2, characterized in that: a protective cover (402) is connected to the side of the hinge (401), and a sliding groove (403) is opened through the inside of the protective cover (402). 4. An energy storage device according to claim 2, characterized in that: a threaded rod (404) is slidably connected inside the sliding groove (403), and a threaded groove (405) is opened on the side of the energy storage box (1). 5. An energy storage device according to claim 1, characterized in that: the moving mechanism (5) comprises a slide groove (501), a first adjusting rod (502), a second adjusting rod (503), a limit groove (504), a limit block (505), an extrusion groove (506), a steel ball (507), a spring (508), a connecting handle (509) and a snap-fit groove (510); The energy storage box (1) is provided with a first adjustment rod (502) at the top, a second adjustment rod (503) is embedded inside the first adjustment rod (502), and a connecting handle (509) is connected to the top of the second adjustment rod (503); The energy storage box (1) and the end of the first adjustment rod (502) are both provided with a sliding groove (501). 6. An energy storage device according to claim 5, characterized in that: a limiting groove (504) is provided on the inner wall of the slide groove (501), and a locking groove (510) is provided on the inner wall of the limiting groove (504). 7. An energy storage device according to claim 5, characterized in that: both sides of the first adjusting rod (502) and the second adjusting rod (503) are connected with limit blocks (505), and the side of the limit block (505) is provided with an extrusion groove (506). 8. An energy storage device according to claim 5, characterized in that: a spring (508) is connected inside the extrusion groove (506), and a steel ball (507) is connected to one end of the spring (508).