Anti-drop type energy storage power supply large equipment fixing structure
By employing anti-tipping and support components in the energy storage power equipment, and utilizing the sliding connection between the I-beam and the mounting base, as well as ball bearing support, the problem of lateral displacement and tipping of the equipment under strong winds has been solved, achieving higher stability and anti-tipping capability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHENZHEN TECHOSS TECH CO LTD
- Filing Date
- 2025-07-30
- Publication Date
- 2026-06-23
Smart Images

Figure CN224401205U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of energy storage power supply fixing technology, and in particular to a large equipment fixing structure for an anti-detachment type energy storage power supply. Background Technology
[0002] The anti-detachment energy storage power supply large equipment fixing structure refers to a set of mechanical structures specifically designed for the safe and stable installation and fixing of large energy storage power supply equipment. Its core objective is to prevent the equipment from accidentally overturning or falling off throughout its entire life cycle.
[0003] Existing anti-detachment energy storage power supplies use a fixed structure to rigidly fix the energy storage power supply equipment to the installation foundation, preventing accidental tipping or falling off during use and ensuring the stability of the equipment during use.
[0004] However, in practical applications, existing anti-detachment energy storage power supplies typically use bolts to connect the energy storage device to the fixed structure for large equipment. This connection method has limited resistance to lateral forces. When encountering strong winds, the bolts are prone to loosening, causing the equipment to shift laterally and tip over, which is not conducive to improving the equipment's anti-tipping ability.
[0005] Therefore, this application provides a large-scale equipment fixing structure for anti-detachment energy storage power supply to meet the requirements. Utility Model Content
[0006] The purpose of this invention is to address the shortcomings of existing technologies and propose a large-scale equipment fixing structure for anti-detachment energy storage power supplies.
[0007] To achieve the above objectives, this utility model adopts the following technical solution: a large-scale equipment fixing structure for an anti-detachment energy storage power supply, comprising an energy storage power supply device, and further comprising:
[0008] An anti-tipping assembly is placed at the bottom of an energy storage power device. The anti-tipping assembly includes a mounting base connected to the bottom of the energy storage power device. An I-beam is connected to the side of the energy storage power device near the mounting base. The energy storage power device is slidably connected to the mounting base via the I-beam.
[0009] A support assembly is placed inside the anti-tipping assembly and is used to reduce the installation difficulty between the mounting base and the I-beam. The support assembly includes a support base connected inside the mounting base. The support base has a rolling groove, and a ball bearing is movably connected inside the rolling groove. The ball bearing is drivenly connected to the mounting base.
[0010] Furthermore, the I-beam is provided with an anti-slip coating.
[0011] The beneficial effect of adopting the above-mentioned further solution is that improving the sliding component helps to improve the stability of the connection between the mounting base and the I-beam.
[0012] Furthermore, fixing plates are connected to both sides of the mounting base.
[0013] The beneficial effect of adopting the above-mentioned further solution is that it completely fixes the I-beam inside the mounting base, ensuring the firmness of the connection between the I-beam and the mounting base.
[0014] Furthermore, a side plate is connected to the bottom of the mounting base.
[0015] The beneficial effects of adopting the above-mentioned further solution are: welding the side plates to the bottom sides of the mounting base increases the contact area between the mounting base and the mounting foundation, reduces the pressure per unit area of the mounting foundation, and avoids damage to the mounting foundation due to excessive local pressure.
[0016] Furthermore, a reinforcing rib connects the mounting base to the side plate.
[0017] The beneficial effect of adopting the above-mentioned further solution is that the reinforcing rib increases the deformation resistance of the mounting base and side plate through its own triangular structure, which is conducive to improving its stability during use.
[0018] Furthermore, a cover plate is threadedly connected to the side of the support base near the ball bearing, and the cover plate is movably connected to the ball bearing.
[0019] The advantages of adopting the above-mentioned further solution are: it facilitates the replacement of the ball bearings and helps to improve the replacement efficiency of the ball bearings.
[0020] Furthermore, the inner diameter of the cover plate is smaller than the diameter of the ball.
[0021] The beneficial effect of adopting the above-mentioned further solution is that it prevents the balls from coming off the rolling groove, which helps to improve the stability of the balls during use.
[0022] Compared with the prior art, the advantages and positive effects of this utility model are as follows:
[0023] 1. By setting up anti-tipping components, the energy storage power equipment is lifted using an external crane and then pushed towards the mounting base. The I-beam moves along the limiting groove on the mounting base, connecting the two. Because the I-beam adopts an I-shaped structure, the protrusion inside its limiting groove will interlock with the mounting base, strengthening the connection between the mounting base and the I-beam and improving the anti-axial force capability between the energy storage power equipment and the mounting base. This solves the problem that traditional bolt connections are prone to loosening, causing lateral displacement or even tipping of the equipment, and helps to improve the anti-tipping capability of the equipment.
[0024] 2. By setting up support components, when the I-beam moves along the mounting base, the balls will support the I-beam from the bottom and roll inside the rolling groove. This reduces the friction between the mounting base and the I-beam, thus helping to reduce the installation difficulty of both. Attached Figure Description
[0025] Figure 1 This is a front view of the large equipment fixing structure of the anti-detachment energy storage power supply according to this utility model;
[0026] Figure 2 This is an exploded view of the anti-tipping component in the large equipment fixing structure of an anti-detachment type energy storage power supply according to this utility model;
[0027] Figure 3 This is a side sectional view of the anti-tipping component in the large equipment fixing structure of an anti-detachment type energy storage power supply according to the present invention;
[0028] Figure 4 This is an exploded view of the support components in the fixed structure of a large-scale equipment of an anti-detachment energy storage power supply according to this utility model.
[0029] Figure Labels
[0030] 1. Energy storage power equipment;
[0031] 2. Anti-tipping components; 21. Mounting base; 22. I-beam; 23. Anti-slip coating; 24. Fixing plate; 25. Side plate; 26. Reinforcing ribs;
[0032] 3. Support components; 31. Support base; 32. Ball bearings; 33. Rolling groove; 34. Cover plate. Detailed Implementation
[0033] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0034] like Figures 1-4 As shown, this utility model provides a technical solution: a large-scale equipment fixing structure for an anti-detachment energy storage power supply, including an energy storage power supply device 1, and further comprising:
[0035] like Figures 1-2As shown, the anti-tipping component 2 is placed at the bottom of the energy storage power device 1. The anti-tipping component 2 includes a mounting base 21 connected to the bottom of the energy storage power device 1. An I-beam 22 is connected to the side of the energy storage power device 1 near the mounting base 21. The energy storage power device 1 is slidably connected to the mounting base 21 through the I-beam 22.
[0036] like Figures 1-3 As shown, support component 3 is placed inside anti-tipping component 2 and is used to reduce the installation difficulty between mounting base 21 and I-beam 22. Support component 3 includes support base 31 connected inside mounting base 21. Support base 31 has a rolling groove 33, and a ball bearing 32 is movably connected inside the rolling groove 33. The ball bearing 32 is drivenly connected to mounting base 21. Mounting base 21 is fixed to mounting foundation using anchor bolts. I-beam 22 is welded to the inside of energy storage power device 1. An external crane is used to lift energy storage power device 1 and then push energy storage power device 1 towards mounting base 21, so that I-beam 22 moves along the upper limit groove opened in mounting base 21, connecting mounting base 21 and I-beam 22 together. Because I-beam 22 has an I-shaped structure, The protrusion inside the limiting groove of the I-beam 22 engages with the inside of the mounting base 21, thereby strengthening the connection between the mounting base 21 and the I-beam 22, improving the anti-lateral force capability between the energy storage power equipment 1 and the mounting base 21, solving the problem of easy loosening of bolts, which causes lateral displacement and tipping of the equipment, and improving the anti-tipping capability of the equipment. Bolts are used to install the support base 31 on the inner side of the mounting base 21. When the I-beam 22 moves along the mounting base 21, the ball bearing 32 supports the I-beam 22 from the bottom and rolls inside the rolling groove 33, reducing the friction between the mounting base 21 and the I-beam 22, thereby reducing the installation difficulty between the mounting base 21 and the I-beam 22. After the mounting base 21 and the I-beam 22 are installed, the bolts are removed and the support base 31 and the ball bearing 32 are taken out.
[0037] Furthermore, such as Figure 2 As shown, an anti-slip coating 23 is provided on the I-beam 22. By spraying the anti-slip coating 23 onto the I-beam 22, the friction between the anti-slip coating 23 and the I-beam 22 is increased, the sliding component is improved, and the stability of the connection between the mounting base 21 and the I-beam 22 is improved.
[0038] Furthermore, such as Figure 2 As shown, both sides of the mounting base 21 are connected to fixing plates 24. The fixing plates 24 are fixed to the outside of the mounting base 21 by using bolts, so that the fixing plates 24 support the I-beam 22 from the outside and completely fix the I-beam 22 inside the mounting base 21, ensuring the firmness of the connection between the I-beam 22 and the mounting base 21.
[0039] Furthermore, such as Figure 2 As shown, the bottom of the mounting base 21 is connected to a side plate 25. By welding the side plate 25 to both sides of the bottom of the mounting base 21, the contact area between the mounting base 21 and the mounting foundation is increased, the pressure per unit area of the mounting foundation is reduced, and the mounting foundation is prevented from being damaged due to excessive local pressure.
[0040] Furthermore, such as Figure 2 As shown, a reinforcing rib 26 is connected between the mounting base 21 and the side plate 25. By welding the reinforcing rib 26 in an array between the side plate 25 and the mounting base 21, the reinforcing rib 26 increases the deformation resistance of the mounting base 21 and the side plate 25 through its own triangular structure, which is beneficial to improving its stability during use.
[0041] Furthermore, such as Figure 4 As shown, a cover plate 34 is threadedly connected to the side of the support base 31 near the ball 32. The cover plate 34 is movably connected to the ball 32. The cover plate 34 is installed on the support base 31 by the thread. This installation method allows the cover plate 34 to be quickly disassembled and installed, which facilitates the replacement of the ball 32 and helps to improve the replacement efficiency of the ball 32.
[0042] Furthermore, such as Figure 4 As shown, the inner diameter of the cover plate 34 is smaller than the diameter of the ball 32. By setting the cover plate 34 with a smaller groove, the cover plate 34 restricts the ball 32 inside the rolling groove 33, preventing the ball 32 from coming out of the rolling groove 33, which helps to improve the stability of the ball 32 during use.
[0043] Working principle: such as Figures 1-4As shown, the side plate 25 and reinforcing rib 26 are first pre-welded to the mounting base 21. The ball bearings 32 are installed inside the rolling groove 33 and fixed with the cover plate 34. The mounting base 21 is placed on the mounting foundation and then fixed with anchor bolts to ensure a firm connection between the mounting base 21 and the mounting foundation. An external crane is used to lift the energy storage power device 1, and then the energy storage power device 1 is pushed towards the mounting base 21, so that the mounting base 21 moves along the upper limit groove opened in the I-beam 22. The ball bearings 32 support the I-beam 22 from the bottom and roll inside the rolling groove 33, reducing the contact between the mounting base 21 and the I-beam. The friction between the steel 22 helps to reduce the installation difficulty between the mounting base 21 and the I-beam 22. After the mounting base 21 and the I-beam 22 are installed, the bolts are removed, and the support base 31 and the ball bearing 32 are taken out. After the mounting base 21 and the I-beam 22 are connected, the protrusion inside the limiting groove of the I-beam 22 is engaged inside the mounting base 21, thereby strengthening the connection between the mounting base 21 and the I-beam 22 and improving the anti-axial force capability between the energy storage power equipment 1 and the mounting base 21. At the same time, the anti-slip coating 23 provides additional friction and improves the stability of the connection between the mounting base 21 and the I-beam 22.
[0044] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any other way. Any person skilled in the art may make changes or modifications to the above-disclosed technical content to create equivalent embodiments for application in other fields. However, any simple modifications, equivalent changes, and modifications made to the above embodiments based on the technical essence of the present utility model without departing from the technical solution of the present utility model shall still fall within the protection scope of the technical solution of the present utility model.
Claims
1. A large equipment fixing structure of a fall-preventing energy storage power supply, comprising an energy storage power supply equipment (1), characterized in that, Also includes: An anti-tipping assembly (2) is placed at the bottom of the energy storage power device (1). The anti-tipping assembly (2) includes a mounting base (21) connected to the bottom of the energy storage power device (1). An I-beam (22) is connected to the side of the energy storage power device (1) near the mounting base (21). The energy storage power device (1) is slidably connected to the mounting base (21) via the I-beam (22). The support assembly (3) is placed inside the anti-tipping assembly (2) and is used to reduce the installation difficulty between the mounting base (21) and the I-beam (22). The support assembly (3) includes a support base (31) connected inside the mounting base (21). The support base (31) is provided with a rolling groove (33). A ball bearing (32) is movably connected inside the rolling groove (33). The ball bearing (32) is connected to the mounting base (21) in a transmission manner.
2. The large equipment fixing structure of the anti-dropping type energy storage power supply according to claim 1, characterized in that, The I-beam (22) is provided with an anti-slip coating (23).
3. The large equipment fixing structure of the anti-dropping type energy storage power supply according to claim 1, characterized in that, The mounting base (21) has fixing plates (24) connected to both sides.
4. The large equipment fixing structure of the anti-dropping type energy storage power supply according to claim 1, characterized in that, The bottom of the mounting base (21) is connected to a side plate (25).
5. The large equipment fixing structure of the anti-dropping type energy storage power supply according to claim 4, characterized in that, A reinforcing rib (26) is connected between the mounting base (21) and the side plate (25).
6. The large equipment fixing structure of the anti-dropping type energy storage power supply according to claim 1, characterized in that, A cover plate (34) is threadedly connected to the side of the support base (31) near the ball (32), and the cover plate (34) is movably connected to the ball (32).
7. The large equipment fixing structure of the anti-dropping type energy storage power supply according to claim 6, characterized in that, The inner diameter of the cover plate (34) is smaller than the diameter of the ball (32).