UPS power supply box body structure
The UPS power supply enclosure structure, designed with mechatronics integration, automatically switches support modes, solving the problems of cumbersome manual operation and unstable support in existing technologies. This enables efficient and stable switching between mobile and fixed modes, improving the operational efficiency and safety of the equipment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUBEI JIACHENDA NEW ENERGY TECH CO LTD
- Filing Date
- 2025-07-09
- Publication Date
- 2026-07-14
AI Technical Summary
Existing UPS power supply enclosures rely on manual operation when switching between mobile and fixed modes, and their stability is insufficient, posing a safety hazard.
It adopts an electromechanical integrated design, and realizes automatic switching of support mode through drive components (forward and reverse motors + worm gear) and linkage components (synchronous pulley belt). Combined with the automatic switching of the ground support and rollers, it enhances support stability, and improves friction through anti-slip pads and wear-resistant sleeves.
It enables one-click mode switching without manual intervention, improving operational efficiency, ensuring the vibration resistance and static stability of the equipment during operation, and enhancing the reliability and safety of the equipment.
Smart Images

Figure CN224502710U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of UPS power supply enclosure technology, specifically to a UPS power supply enclosure structure. Background Technology
[0002] The UPS power supply enclosure is a key component of an integrated uninterruptible power supply system, protecting internal components and distributing power. Its design must balance structural strength, heat dissipation, and electromagnetic compatibility. It typically uses metal materials such as cold-rolled steel or aluminum alloy to ensure physical protection for core components such as rectifiers, inverters, battery banks, and static switches. The internal layout optimizes airflow, using a combination of ventilation holes and fans to achieve efficient heat dissipation, ensuring stable operation in ambient temperatures ranging from 5℃ to 40℃. External interfaces include AC input, bypass output, battery connection, and multiple load sockets, supporting three-phase or single-phase power supply modes, with an output voltage range covering 220V / 380V. Some high-end models are equipped with intelligent monitoring screens that display voltage, frequency, load rate, and battery status in real time. Protection ratings typically reach IP20 or higher, providing dustproof, moisture-proof, and electromagnetic interference-resistant capabilities, making them suitable for scenarios with stringent power continuity requirements, such as data centers, medical equipment, and industrial control systems.
[0003] A search revealed that publication number CN207426752U discloses a mobile enclosure for a UPS power supply, comprising a UPS power supply body and a cylindrical shell. Each of the two end faces of the cylindrical shell has a through hole at its center. The UPS power supply body is disposed inside the cylindrical shell, and two fixed shafts are located at both ends of the UPS power supply body. The two fixed shafts are respectively disposed within the through holes and rotatably connected to the through holes via bearings. Voltage input and voltage output sockets are respectively provided within the two fixed shafts. This utility model's mobile enclosure for a UPS power supply, by designing the shell as a cylindrical structure, allows for easy movement by rolling the cylindrical shell on the ground. Furthermore, a rotatable triangular plate is provided on the end face of the cylindrical shell, allowing it to be placed on non-level surfaces.
[0004] The problem with the aforementioned mobile enclosure for a UPS power supply is that:
[0005] 1. Switching between mobile and stationary modes requires manual operation.
[0006] The comparison file shows that movement is achieved by rolling the cylindrical shell, while when stationary, the triangular plate needs to be manually adjusted to adapt to the ground. This method requires manual intervention, is cumbersome, and is inefficient in emergency situations.
[0007] II. Insufficient support stability
[0008] The combination of a cylindrical shell and a triangular plate has a limited contact area on non-horizontal ground, and the friction between the triangular plate and the ground is low after rotation, which may cause the equipment to slip when vibrating or under load, posing a safety hazard. Utility Model Content
[0009] This invention proposes a UPS power supply enclosure structure that solves the problems of existing technologies where switching between mobile and fixed modes relies on manual operation and where support stability is insufficient.
[0010] A UPS power supply enclosure structure includes a support platform and a UPS power supply body mounted on the top of the support platform, characterized in that: a protective compartment is fixedly connected to the side of the support platform.
[0011] Drive components are installed inside the protective chamber;
[0012] A linkage component installed at the bottom of the support platform and inside the protective chamber, capable of rotating in conjunction with the drive component.
[0013] A switching component is installed on the outside of the linkage component to switch between ground support and ground support modes.
[0014] Preferably, the driving component includes:
[0015] A built-in frame symmetrically and fixedly connected to the inside of the protective compartment;
[0016] A worm gear is rotatably connected to the middle of the two sets of built-in frames.
[0017] Preferably, the driving component further includes:
[0018] A forward and reverse motor is fixedly installed on the outside of a set of the built-in frames;
[0019] The output end of the forward and reverse motors is fixedly connected to the worm gear.
[0020] Preferably, the driving component includes:
[0021] Rotary shaft connected to the inside of the protective compartment;
[0022] A worm gear fixedly connected to the outside of the rotating shaft;
[0023] The worm gear is in contact with the worm and is connected in a meshing rotational manner.
[0024] Preferably, the linkage component includes:
[0025] Symmetrical rotating rods are arranged at the bottom of the support platform;
[0026] One set of the rotating rods and the rotating shaft are fixedly connected;
[0027] Another set of the rotating rods is rotatably connected to the inner wall of the protective chamber.
[0028] Preferably, the linkage component further includes:
[0029] Synchronous pulleys are fixedly connected to the outside of each of the aforementioned rotating rods;
[0030] A timing belt fitted over the outside of the two sets of timing pulleys;
[0031] The synchronous belt and the synchronous pulley are connected by meshing transmission.
[0032] Preferably, the switching component includes:
[0033] Symmetrically fixed ground supports are connected to both sides of the rotating rod;
[0034] Anti-slip pads are fixedly connected to the top of each of the aforementioned support bases.
[0035] Preferably, the switching component further includes:
[0036] Rotary connecting columns at the bottom of each of the aforementioned support bases;
[0037] The legs are fixedly connected to the bottom of the rotating column.
[0038] Preferably, the switching component further includes:
[0039] Rotate the rollers connected to the inside of the legs.
[0040] Preferably, the switching component further includes:
[0041] A wear-resistant sleeve fitted onto the outside of the roller.
[0042] The beneficial effects of this utility model are as follows:
[0043] I. Automated Switching Support Method
[0044] Improvements: Automatic switching between the ground support and the rollers is achieved through a drive component (forward and reverse motors + worm gear) and a linkage component (synchronous belt).
[0045] Advantages: No manual intervention is required; mode switching can be completed with a single click to start the motor, significantly improving operational efficiency and making it suitable for scenarios requiring rapid deployment (such as data center emergency response).
[0046] II. Stability Optimization of Dual-Mode Support
[0047] Areas for improvement:
[0048] In the fixed mode, the anti-slip pad at the bottom of the support provides stable support by increasing the coefficient of friction of the contact surface;
[0049] In mobile mode, the tripod and swivel design allows the wheels to rotate in all directions, while wear-resistant sleeves enhance durability.
[0050] Advantages: The ground support has a larger contact area with the ground, and the introduction of anti-slip pad materials (such as rubber) further inhibits slippage, ensuring the vibration resistance and static stability of the equipment during operation.
[0051] III. Compact Structure and Self-Locking Protection
[0052] Improvement: The worm gear transmission has a self-locking characteristic to prevent the support state from changing unexpectedly due to external forces (such as vibration) after switching.
[0053] Advantages: While improving structural compactness, it avoids the risk of backlash that may occur with traditional gear transmission, thus enhancing the long-term reliability of the equipment. Attached Figure Description
[0054] The present invention will now be described in further detail with reference to the accompanying drawings and specific embodiments.
[0055] Figure 1 This is a schematic diagram of the overall device of this utility model. Figure 1 ;
[0056] Figure 2 This is a schematic diagram of the overall device of this utility model. Figure 2 ;
[0057] Figure 3 This is a schematic diagram showing the structural connection of the drive component and the linkage component of this utility model;
[0058] Figure 4 This is a schematic diagram showing the structural connection of the linkage component and the switching component of this utility model;
[0059] In the diagram: 1. Support platform; 11. Protective compartment; 2. Drive assembly; 21. Forward and reverse motor; 211. Worm gear; 22. Internal frame; 23. Rotary shaft; 231. Worm wheel; 3. Linkage assembly; 31. Rotating rod; 311. Synchronous pulley; 32. Synchronous belt; 4. Switching assembly; 41. Ground support; 411. Anti-slip pad; 42. Leg; 421. Rotating column; 43. Roller; 431. Wear-resistant sleeve; 5. UPS power supply body. Detailed Implementation
[0060] The technical solutions of this utility model will be clearly and completely described below with reference to the embodiments of this utility model. Obviously, the described embodiments are only some embodiments of this utility model, and not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of this utility model.
[0061] Please see Figure 1 and Figure 2 and Figure 3 and Figure 4 This utility model provides a technical solution: a UPS power supply box structure, including a support platform 1 and a UPS power supply body 5 assembled on the top of the support platform 1, characterized in that: a protective compartment 11 is fixedly connected to the side of the support platform 1.
[0062] Drive component 2 is installed inside the protective chamber 11;
[0063] A linkage component 3, which is installed at the bottom of the support platform 1 and inside the protective chamber 11, and can rotate in conjunction with the drive component 2;
[0064] A switching component 4, located on the outside of the linkage component 3, is capable of switching between ground support and other modes.
[0065] This design addresses the core issues of inefficiency in manual operation and unstable support in the comparative documents through mechatronics design. At the same time, it introduces self-locking transmission and modular components, taking into account automation, stability and safety, and demonstrating the significant progress of UPS power supply enclosures in terms of intelligence and reliability.
[0066] Please see Figure 3 Driver component 2 includes:
[0067] The built-in frame 22 is symmetrically and fixedly connected to the inside of the protective compartment 11;
[0068] The worm gear 211 is rotatably connected to the middle of the two sets of built-in frames 22.
[0069] Driver component 2 also includes:
[0070] A forward and reverse motor 21 is fixedly installed on the outside of a set of built-in frames 22;
[0071] The output end of the forward and reverse motor 21 is fixedly connected to the worm gear 211.
[0072] Driver component 2 includes:
[0073] Rotate the shaft 23 connected to the inside of the protective compartment 11;
[0074] A worm gear 231 is fixedly connected to the outside of the rotating shaft 23;
[0075] The worm gear 231 is in contact with the worm 211 and is in a meshing rotational connection;
[0076] The self-locking effect of the worm gear 231 and worm 211 can prevent loosening after rotation.
[0077] Linkage component 3 includes:
[0078] Rotary rods 31 are symmetrically arranged at the bottom of the support platform 1;
[0079] One set of rotating rods 31 is fixedly connected to the rotating shaft 23;
[0080] Another set of rotating rods 31 is rotatably connected to the inner wall of the protective chamber 11.
[0081] Please see Figure 3 The linkage component 3 also includes:
[0082] Synchronous pulleys 311 are fixedly connected to the outside of each rotating rod 31;
[0083] Synchronous belt 32 is fitted onto the outside of the two sets of synchronous pulleys 311;
[0084] Synchronous belt 32 and synchronous pulley 311 are connected by meshing transmission;
[0085] This design allows the two sets of rotating rods 31 to rotate synchronously and in the same direction.
[0086] Please see Figure 4 Switching component 4 includes:
[0087] The ground support bases 41 are symmetrically fixedly connected to both sides of the rotating rod 31;
[0088] Anti-slip pads 411 are fixedly connected to the top of each support base 41;
[0089] The friction between the support base 41 and the ground can be increased by providing an anti-slip pad 411 on top of the support base 41.
[0090] Switching component 4 also includes:
[0091] Rotary connecting column 421 to the bottom of each support base 41;
[0092] The rotating column 421 causes the roller 43 to rotate at any angle on the ground.
[0093] The bracket 42 is fixedly connected to the bottom of the rotating column 421;
[0094] Switching component 4 also includes:
[0095] Rotate the roller 43 connected to the inside of the leg 42;
[0096] Switching component 4 also includes:
[0097] Wear-resistant sleeve 431 fitted onto the outside of roller 43;
[0098] The wear resistance of roller 43 can be increased by providing a wear-resistant sleeve 431 on the outside of roller 43.
[0099] Working principle:
[0100] When it is necessary to move the UPS power supply body 5 to the target area, the forward and reverse motor 21 can be started to drive the worm gear 211 to rotate. Under the meshing action of the worm gear 211 and the worm wheel 231, the rotating shaft 23 located inside the worm wheel 231 will rotate synchronously. At this time, under the meshing cooperation of the two sets of synchronous pulleys 311 and the synchronous belt 32, the corresponding rotating rod 31 can rotate synchronously in the same direction. When the rotating rod 31 rotates 180 degrees, the roller 43 replaces the ground support 41 and contacts the ground. At this time, the staff can move the UPS power supply body 5 to the target area through the universal rotating roller 43.
[0101] Meanwhile, when the UPS power supply body 5 moves to the target area, the forward and reverse motor 21 is started to make the rotating rod 31 rotate 180 degrees again. At this time, the ground support 41 and the anti-slip pad 411 can replace the roller 43 to support the UPS power supply body 5 on the ground.
[0102] The above are merely preferred embodiments of the present utility model and are not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.
Claims
1. A UPS power supply enclosure structure, comprising a support platform (1) and a UPS power supply body (5) mounted on top of the support platform (1), characterized in that: The support platform (1) is fixedly connected to a protective compartment (11) on its side. The drive assembly (2) is installed inside the protective chamber (11); A linkage component (3) is installed at the bottom of the support platform (1) and inside the protective chamber (11) and can rotate in conjunction with the drive component (2). A switching component (4) is installed outside the linkage component (3) to switch between ground support and ground support modes.
2. The UPS power supply enclosure structure according to claim 1, characterized in that, The driving component (2) includes: The built-in frame (22) is symmetrically fixedly connected to the inside of the protective compartment (11); The worm gear (211) is rotatably connected to the middle of the two sets of built-in frames (22).
3. The UPS power supply enclosure structure according to claim 2, characterized in that, The driving component (2) also includes: A forward and reverse motor (21) is fixedly installed on the outside of a set of built-in frames (22); The output end of the forward and reverse motor (21) is fixedly connected to the worm gear (211).
4. The UPS power supply enclosure structure according to claim 2, characterized in that, The driving component (2) includes: Rotate the shaft (23) connected to the inside of the protective chamber (11); A worm gear (231) is fixedly connected to the outside of the rotating shaft (23); The worm wheel (231) is in contact with the worm (211) and is in a meshing rotational connection.
5. A UPS power supply enclosure structure according to claim 4, characterized in that, The linkage component (3) includes: Rotary rods (31) are symmetrically arranged at the bottom of the support platform (1). One set of the rotating rods (31) and the rotating shaft (23) are fixedly connected; Another set of the rotating rods (31) is rotatably connected to the inner wall of the protective chamber (11).
6. The UPS power supply enclosure structure according to claim 5, characterized in that, The linkage component (3) also includes: Synchronous pulleys (311) are fixedly connected to the outside of each of the aforementioned rotating rods (31). Synchronous belts (32) are fitted on the outside of the two sets of synchronous pulleys (311); The synchronous belt (32) and the synchronous pulley (311) are connected by meshing transmission.
7. A UPS power supply enclosure structure according to claim 5, characterized in that, The switching component (4) includes: The ground support (41) is symmetrically fixedly connected to both sides of the rotating rod (31); Anti-slip pads (411) are fixedly connected to the top of each of the aforementioned support bases (41).
8. A UPS power supply enclosure structure according to claim 7, characterized in that, The switching component (4) also includes: Rotary connecting column (421) to the bottom of each of the said support bases (41); The legs (42) are fixedly connected to the bottom of the rotating column (421).
9. A UPS power supply enclosure structure according to claim 8, characterized in that, The switching component (4) also includes: Rotate the roller (43) connected to the inside of the leg (42).
10. A UPS power supply enclosure structure according to claim 9, characterized in that, The switching component (4) also includes: A wear-resistant sleeve (431) is fitted onto the outside of the roller (43).