A battery module installation platform for energy storage cabinets
By designing an energy storage cabinet battery module installation platform, and utilizing components such as hydraulic push rods, electric push rods, and bevel gears, the efficient and precise installation of battery modules was achieved. This solved the problem of multiple people working together to move the modules during the traditional installation process, and improved work efficiency and accuracy.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SUZHOU FENGHAIYANG ENERGY TECHNOLOGY CO LTD
- Filing Date
- 2025-06-30
- Publication Date
- 2026-07-03
AI Technical Summary
Traditional battery module installation requires multiple people to move the modules, resulting in slow placement, inaccurate positioning, and low work efficiency.
Design an energy storage cabinet battery module installation platform, which adopts components such as hydraulic push rods, electric push rods, bevel gears, threaded rods and clamping plates to achieve precise positioning and efficient installation of battery modules through mechanized means, including hydraulic push rods pushing connecting rods upward, motor-driven bevel gears meshing to drive threaded rods to rotate, clamping plate spacing adjustment and rollers assisting movement.
It enables precise positioning and efficient installation of battery modules, reducing manpower requirements and improving work efficiency and installation accuracy.
Smart Images

Figure CN224450205U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of energy storage cabinet technology, and more specifically, to an energy storage cabinet battery module installation platform. Background Technology
[0002] An energy storage cabinet is an integrated energy storage system, mainly used to store electrical energy and release it when needed. It is widely used in industrial and commercial energy storage, new energy power generation support and emergency power supply. It is usually composed of multiple lithium-ion battery modules, and a lithium-ion battery module is usually composed of multiple individual lithium-ion batteries.
[0003] Traditionally, the assembly and installation of battery modules are usually done manually by workers, requiring multiple people to work together to move and place the battery modules into the energy storage cabinet. This results in slow placement speed, lack of precision, and low work efficiency. Utility Model Content
[0004] The purpose of this utility model is to provide a battery module installation platform for energy storage cabinets, which can accurately place battery modules into the energy storage cabinets without the need for multiple people to carry them, thus saving labor and improving work efficiency.
[0005] The above-mentioned technical objective of this utility model is achieved through the following technical solution: an energy storage cabinet battery module installation platform, including a base, multiple universal wheels installed under the base, a push rod connected to the base, columns connected to both sides above the base, a hydraulic push rod fixedly installed on the base, a slide rail connected to one side of the column, a sliding rod slidably connected inside the column, a fixed block connected to one end of the sliding rod, and a connecting rod connected to the fixed block;
[0006] The connecting rod is rotatably connected to two wheels, and a steel cable is provided on the wheels. One end of the steel cable is connected to a connecting block, and a mounting platform is connected to the connecting block. Multiple rollers are rotatably mounted on the mounting platform, and an electric push rod is fixedly mounted below the mounting platform. An L-shaped plate is connected to the movable end of the electric push rod, and a gear box is connected to the L-shaped plate.
[0007] Hollow plates are connected to both sides of the gear box. A motor is fixedly installed on the gear box. A bevel gear one is connected to the output shaft of the motor. A bevel gear two is rotatably connected to both sides of the gear box. A threaded rod is connected to the bevel gear two. A threaded tube is threadedly connected to the threaded rod. A clamping plate is connected to one end of the threaded tube.
[0008] Furthermore, the overall design of the rotating wheel is I-shaped, and the steel cable is specifically set in the I-shaped recess of the rotating wheel.
[0009] Furthermore, a buffer pad is connected to the top of the column, and the sliding rod passes through the buffer pad, which is made of rubber.
[0010] Furthermore, the movable end of the hydraulic push rod is fixedly connected to the connecting rod, and the end of the steel cable away from the connecting block is fixedly connected to the base.
[0011] Furthermore, mating blocks are connected to both sides of the mounting platform, and the slide rail has a T-shaped cross-section, with the mating blocks slidingly engaging with the slide rail.
[0012] Furthermore, the multiple rollers on the mounting platform are arranged at equal intervals, and the four omnidirectional wheels are evenly distributed in a rectangular array.
[0013] Furthermore, the first bevel gear and the second bevel gear mesh with each other, and both the first bevel gear and the second bevel gear are located inside the gearbox.
[0014] Furthermore, the threaded rod is rotatably connected to both sides of the gear box via bearings, and the clamping plate is bent into an L-shape and in close contact with the outer wall of the hollow plate.
[0015] Furthermore, the threaded tube slides within the hollow plate and contacts the inner wall of the hollow plate, and a strip groove is formed on the inner wall of the hollow plate.
[0016] Furthermore, the threaded tube is connected to both sides with protrusions, which slide within the strip groove.
[0017] Compared to existing technologies, the advantages of this solution are as follows:
[0018] 1. This solution utilizes hydraulic push rods, connecting rods, rotating wheels, steel cables, electric push rods, and L-shaped plates. After the battery modules are assembled on the mounting platform, the hydraulic push rods are activated to move the connecting rods upwards. As the connecting rods and rotating wheels rise, the steel cables pull the mounting platform upwards, thereby lifting the entire battery module. This allows workers to easily place the battery modules into the higher part of the energy storage cabinet without the need for multiple people to work together. Furthermore, activating the electric push rods moves the L-shaped plates, which in turn move the hollow plates and clamping plates, pushing the battery modules into the energy storage cabinet. This eliminates the need for multiple people to simultaneously place the battery modules, significantly improving work efficiency.
[0019] 2. This solution involves setting up a motor, bevel gear one, bevel gear two, threaded rods, threaded tubes, and clamping plates. Starting the motor drives bevel gear one to rotate, and the meshing of bevel gear one and bevel gear two synchronously drives the two threaded rods to rotate. This allows the threaded tubes, which are threaded into the threaded rods, to slide within the hollow plate. Adjusting the distance between the two clamping plates allows them to hold and fix batteries or battery packs of different sizes, preventing them from sliding and facilitating assembly by workers. The clamping plates also position the battery modules, making it easier to push them into the energy storage cabinet with precision. Attached Figure Description
[0020] Figure 1 A three-dimensional structural diagram illustrating this utility model;
[0021] Figure 2 This is a three-dimensional structural diagram of the base used to illustrate the present invention;
[0022] Figure 3 This is a schematic diagram of the cross-sectional structure of the mounting platform used to illustrate this utility model;
[0023] Figure 4 This is a schematic cross-sectional view of the gearbox and hollow plate used to illustrate the present invention.
[0024] In the diagram: 1. Base; 2. Casters; 3. Hand push rod; 4. Column; 5. Hydraulic push rod; 6. Slide rail; 7. Sliding rod; 8. Fixing block; 9. Connecting rod; 10. Rotary wheel; 11. Steel cable; 12. Connecting block; 13. Mounting platform; 14. Roller; 15. Electric push rod; 16. L-shaped plate; 17. Gear box; 18. Hollow plate; 19. Motor; 20. Bevel gear one; 21. Bevel gear two; 22. Threaded rod; 23. Threaded pipe; 24. Clamping plate; 25. Buffer pad; 26. Mating block; 27. Strip groove; 28. Protrusion. Detailed Implementation
[0025] The utility model will be further described in detail below with reference to the accompanying drawings and specific embodiments. The following embodiments are only descriptive and are not intended to limit the scope of protection of this utility model.
[0026] Example 1: A battery module installation platform for an energy storage cabinet, such as Figure 1-4 As shown, the system includes a base 1, with multiple casters 2 mounted below the base 1. A push rod 3 is connected to the base 1. Columns 4 are connected to the upper sides of the base 1. A buffer pad 25 is connected to the top of each column 4. A sliding rod 7 passes through the buffer pad 25, which is made of rubber. A hydraulic push rod 5 is fixedly mounted on the base 1, with its movable end fixedly connected to a connecting rod 9. The end of a steel cable 11 away from the connecting block 12 is fixedly connected to the base 1. A slide rail 6 is connected to one side of each column 4, and a sliding rail is slidably connected inside each column 4. The movable rod 7 and the sliding rod 7 are connected to a fixed block 8 at one end. A connecting rod 9 is connected to the fixed block 8. The two ends of the connecting rod 9 are rotatably connected to a rotating wheel 10. A steel cable 11 is set on the rotating wheel 10. The rotating wheel 10 is designed in an I-shape. The steel cable 11 is specifically set in the I-shaped recess of the rotating wheel 10. One end of the steel cable 11 is connected to a connecting block 12. A mounting platform 13 is connected to the connecting block 12. The mounting platform 13 is connected to two mating blocks 26 on both sides. The slide rail 6 has a T-shaped cross-section. The mating blocks 26 slide with the slide rail 6.
[0027] In practical applications, the hydraulic push rod 5 pushes the connecting rod 9, which in turn drives the rotating wheel 10 and the fixed block 8 to move upward. This causes the sliding rod 7 to slide and rise within the column 4, allowing the steel cable 11 to pull the mounting platform 13 upward. At this time, the mating block 26 can slide on the slide rail 6, thus guiding the movement of the mounting platform 13 and preventing it from tilting or shifting during the lifting and lowering process, thereby improving the stability of the movement. The mounting platform 13, which moves up and down via the steel cable 11, allows workers to easily place the battery modules into the energy storage cabinet at different heights without the need for manual handling, thus improving work efficiency.
[0028] Example 2: A battery module installation platform for an energy storage cabinet, which differs from Examples 1 and 3 in that, as shown in Example 2... Figure 3 As shown, multiple rollers 14 are rotatably mounted on the mounting platform 13. The multiple rollers 14 on the mounting platform 13 are arranged at equal intervals. There are four casters 2 evenly distributed in a rectangular array. An electric push rod 15 is fixedly mounted below the mounting platform 13. An L-shaped plate 16 is connected to the movable end of the electric push rod 15. A gear box 17 is connected to the L-shaped plate 16. Hollow plates 18 are connected to both sides of the gear box 17.
[0029] In practical applications, the L-shaped plate 16 is moved by the electric push rod 15, which in turn causes the gear box 17 and the hollow plate 18 to move as a whole. This allows the battery module held by the clamping plate 24 to move. When the battery module moves, the roller 14 rolls synchronously, which assists in the movement of the battery module, improves the flexibility of the battery module movement, and makes it easier to push the battery module into the energy storage cabinet, thus improving the installation efficiency.
[0030] Example 3: A battery module installation platform for an energy storage cabinet, which differs from Example 1 in that, as shown in Example 1... Figure 4 As shown, a motor 19 is fixedly installed on the gear box 17. The output shaft of the motor 19 is connected to a bevel gear 20. A bevel gear 21 is rotatably connected to both sides of the gear box 17. The bevel gear 20 and the bevel gear 21 mesh with each other. Both the bevel gear 20 and the bevel gear 21 are located inside the gear box 17. A threaded rod 22 is connected to the bevel gear 21. A threaded tube 23 is threadedly connected to the threaded rod 22. The threaded tube 23 slides inside the hollow plate 18 and contacts the inner wall of the hollow plate 18. A strip groove 27 is opened on the inner wall of the hollow plate 18. Protrusions 28 are connected to both sides of the threaded tube 23. The protrusions 28 slide in the strip groove 27. A clamping plate 24 is connected to one end of the threaded tube 23. The threaded rod 22 is rotatably connected to both sides of the gear box 17 through bearings. The clamping plate 24 is bent into an L-shape and is in close contact with the outer wall of the hollow plate 18.
[0031] In practical applications, by starting the motor 19 to rotate the bevel gear 20, the bevel gear 20 drives the two bevel gears 21, which in turn drive the two threaded rods 22 to rotate. When the threaded rods 22 rotate, the threaded tube 23 can slide within the hollow plate 18, while the protrusion 28 slides along the strip groove 27, thereby guiding and restricting it. This allows the threaded tube 23 to smoothly push or pull the clamping plate 24 to move, thereby adjusting the distance between the two clamping plates 24, thus clamping and fixing battery modules of different sizes for positioning and preventing skewing.
[0032] Working principle: The motor 19 drives the bevel gear 20 to rotate. The meshing of bevel gear 20 and bevel gear 21 causes the two bevel gears 21 to drive the two threaded rods 22 to rotate. This causes the threaded tube 23, which is threaded into the threaded rods 22, to slide within the hollow plate 18, thereby moving the clamping plate 24. Adjusting the distance between the two clamping plates 24 allows them to hold batteries or battery packs of different sizes, preventing slippage and facilitating assembly. Then, the hydraulic push rod 5 is activated to push the connecting rod 9. The upward movement allows the steel cable 11 to pull the mounting platform 13 upward, thereby raising the battery module as a whole. This makes it easier for staff to place the battery module at a higher position in the energy storage cabinet without the need for multiple people to work together to move it. Finally, the electric push rod 15 is activated to push the L-shaped plate 16 to move, which in turn moves the hollow plate 18 and the clamping plate 24, thus pushing the battery module. As the battery module moves, the roller 14 will roll synchronously to assist in the movement of the battery module, improve the flexibility of the battery module movement, and make it easier to push the battery module into the energy storage cabinet.
[0033] This specific embodiment is merely an explanation of the present utility model and is not intended to limit the present utility model. After reading this specification, those skilled in the art can make modifications to this embodiment without contributing any inventive step, but as long as they are within the scope of the claims of the present utility model, they are protected by patent law.
Claims
1. An energy storage cabinet battery module mounting platform, characterized in that, include: Base (1); Multiple casters (2) are installed under the base (1), a push rod (3) is connected to the base (1), columns (4) are connected to the upper sides of the base (1), a hydraulic push rod (5) is fixedly installed on the base (1), a slide rail (6) is connected to one side of the column (4), a sliding rod (7) is slidably connected inside the column (4), a fixing block (8) is connected to one end of the sliding rod (7), and a connecting rod (9) is connected to the fixing block (8); The connecting rod (9) is rotatably connected to two wheels (10) at both ends. A steel cable (11) is provided on the wheel (10). A connecting block (12) is connected to one end of the steel cable (11). An installation platform (13) is connected to the connecting block (12). Multiple rollers (14) are rotatably installed on the installation platform (13). An electric push rod (15) is fixedly installed below the installation platform (13). An L-shaped plate (16) is connected to the movable end of the electric push rod (15). A gear box (17) is connected to the L-shaped plate (16). Hollow plates (18) are connected to both sides of the gear box (17). A motor (19) is fixedly installed on the gear box (17). A bevel gear (20) is connected to the output shaft of the motor (19). A bevel gear (21) is rotatably connected to both sides of the gear box (17). A threaded rod (22) is connected to the bevel gear (21). A threaded tube (23) is threadedly connected to the threaded rod (22). A clamping plate (24) is connected to one end of the threaded tube (23).
2. The energy storage cabinet battery module mounting platform of claim 1, wherein, The wheel (10) is designed in an I-shape, and the steel cable (11) is specifically set in the I-shaped recess of the wheel (10).
3. The energy storage cabinet battery module mounting platform of claim 1, wherein, The top of the column (4) is connected to a buffer pad (25), and the sliding rod (7) passes through the buffer pad (25). The buffer pad (25) is made of rubber.
4. The energy storage cabinet battery module mounting platform of claim 1, wherein, The movable end of the hydraulic push rod (5) is fixedly connected to the connecting rod (9), and the end of the steel cable (11) away from the connecting block (12) is fixedly connected to the base (1).
5. The energy storage cabinet battery module mounting platform of claim 1, wherein, The mounting platform (13) is connected to mating blocks (26) on both sides. The slide rail (6) has a T-shaped cross-section and the mating blocks (26) slide in cooperation with the slide rail (6).
6. The energy storage cabinet battery module mounting platform of claim 1, wherein, The multiple rollers (14) on the mounting platform (13) are arranged at equal intervals, and the four casters (2) are evenly distributed in a rectangular array.
7. The energy storage cabinet battery module mounting platform of claim 1, wherein, The first bevel gear (20) and the second bevel gear (21) mesh with each other, and both the first bevel gear (20) and the second bevel gear (21) are located inside the gear box (17).
8. The energy storage cabinet battery module mounting platform of claim 1, wherein, The threaded rod (22) is rotatably connected to both sides of the gear box (17) via bearings, and the clamping plate (24) is bent into an L-shape and is in contact with the outer wall of the hollow plate (18).
9. The energy storage cabinet battery module mounting platform of claim 1, wherein, The threaded tube (23) slides inside the hollow plate (18) and the threaded tube (23) contacts the inner wall of the hollow plate (18). A strip groove (27) is provided on the inner wall of the hollow plate (18).
10. The energy storage tank battery module mounting platform of claim 9, wherein, The threaded tube (23) is connected to two protrusions (28) on both sides, and the protrusions (28) slide in the strip groove (27).