Energy storage module hoisting tool

By designing clamping modules, limit plates, and rotating support modules for the energy storage module hoisting fixture, the swaying problem during the hoisting process of the energy storage module was solved, achieving precise and stable hoisting and improving safety.

CN224337022UActive Publication Date: 2026-06-09HUIZHOU DESAY INTELLIGENT ENERGY STORAGE CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HUIZHOU DESAY INTELLIGENT ENERGY STORAGE CO LTD
Filing Date
2025-06-30
Publication Date
2026-06-09

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  • Figure CN224337022U_ABST
    Figure CN224337022U_ABST
Patent Text Reader

Abstract

The utility model provides a kind of energy storage module hoisting tool, including hoisting mainboard, the clamping module being oppositely arranged along the length direction of the hoisting mainboard and the limiting plate being oppositely arranged along the width direction of the hoisting mainboard, rotating support module, the clamping module the limiting plate and the rotating support module are all connected with the hoisting mainboard;The clamping module is used for clamping energy storage module, the limiting plate is used for the limiting of energy storage module, and the rotating support module is used for holding the lower end of the energy storage module;The clamping module includes clamping drive component and the clamping piece connected with the drive end of the clamping drive component, and the protruding block for the positioning of the energy storage module is formed on the clamping piece;A kind of energy storage module hoisting tool provided by the utility model can realize accurate and stable hoisting operation of energy storage module, improve operation safety.
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Description

Technical Field

[0001] This utility model belongs to the field of energy storage module technology, specifically relating to an energy storage module hoisting fixture. Background Technology

[0002] An energy storage module is a device that integrates multiple energy storage units, such as batteries and supercapacitors, for storing and releasing electrical energy. As a core unit for energy storage and management, energy storage modules have deeply penetrated into power systems, transportation, industry, and civil applications, such as grid-scale energy storage, commercial and industrial energy storage, and transportation and mobile energy storage.

[0003] In some testing or assembly requirements of energy storage modules, it is necessary to hoist the energy storage modules. Existing hoisting tools usually involve setting positioning pins and inserting them into the pre-drilled hoisting holes on the energy storage module to hoist it. However, in practical applications, it has been found that if the energy storage module shakes during the hoisting process, the positioning pins may easily disengage from the hoisting holes, causing the energy storage module to slip and fall, which can easily damage the product and also poses a safety hazard. Summary of the Invention

[0004] To address the shortcomings of the existing technology, this utility model provides a hoisting fixture for energy storage modules, which enables precise and stable hoisting operations of energy storage modules and improves operational safety.

[0005] The technical effects to be achieved by this utility model are realized through the following technical aspects:

[0006] This utility model provides a hoisting fixture for an energy storage module, including a hoisting main board, a clamping module disposed opposite to each other along the length direction of the hoisting main board, a limiting plate disposed opposite to each other along the width direction of the hoisting main board, and a rotating support module, wherein the clamping module, the limiting plate and the rotating support module are all connected to the hoisting main board;

[0007] The clamping module is used to clamp the energy storage module, the limiting plate is used to limit the energy storage module, and the rotating support module is used to support the lower end of the energy storage module.

[0008] The clamping module includes a clamping drive assembly and a clamping member connected to the drive end of the clamping drive assembly. The clamping member has protrusions formed on it for positioning the energy storage module.

[0009] The rotating support module includes a connecting plate, a support plate, and a first pin. The upper end of the connecting plate is fixedly connected to the hoisting main plate, and the lower end of the connecting plate is rotatably connected to the support plate. The support plate rotates to the lower end of the energy storage module, and the first pin locks the support plate to the connecting plate or the limiting plate.

[0010] In some implementations, a first positioning hole is formed at the lower end of the connecting plate, and a second positioning hole matching the first positioning hole is formed on the support plate;

[0011] After the support plate is rotated to the lower end of the energy storage module, the first pin is inserted into the first positioning hole and the second positioning hole to lock the support plate, so that the support plate provides stable support for the energy storage module and improves the stability and safety of the energy storage module hoisting operation.

[0012] In some implementations, the clamping drive assembly includes a drive element, a connecting rod, and a connecting frame;

[0013] The two ends of the connecting rod are respectively connected to the driving end of the driving component and the connecting frame. The clamping component is disposed on the connecting frame. Through the linkage between the connecting rod and the connecting frame, the driving component can indirectly drive the clamping movement of the clamping component to achieve the clamping effect on the energy storage module.

[0014] In some implementations, the connecting frame includes a connecting motherboard and connecting side plates disposed on both sides of the connecting motherboard;

[0015] The hoisting main board is located at the lower end of the connecting main board and between the two connecting side plates;

[0016] The clamping components are mounted on the connecting side plates on both sides.

[0017] In some implementations, the clamping module further includes a clamping guide assembly;

[0018] The clamping guide assembly includes a guide rail and a slider that slides along the guide rail, the guide rail being distributed along the driving direction of the driving member;

[0019] The connecting frame connects to the slider, and the guide rail and slider guide and slide to improve the stability of the clamping component during the clamping movement.

[0020] In some implementations, the clamping module further includes a second pin;

[0021] The second pin is used to lock the connecting frame to the hoisting main board to prevent the clamping parts from moving after clamping the energy storage module, thereby improving the stability of the hoisting operation.

[0022] In some implementations, the clamping module further includes a check valve;

[0023] The check valve is located between the connecting main board and the hoisting main board. It is used to prevent the connecting main board from moving after the clamping component clamps the energy storage module, thereby improving the stability of the hoisting operation.

[0024] In some implementations, a support frame is also provided that is positioned opposite to the main lifting plate in the width direction;

[0025] The support frame is located below the hoisting main board and is used to support the hoisting main board, improve the alignment accuracy of the hoisting main board, and thus improve the precision of the hoisting operation.

[0026] In some implementations, a limit block is provided at the upper end of the support frame;

[0027] A guide slope is formed on the limiting block, which is used to guide the hoisting main board during descent.

[0028] In some implementations, a first positioning block and a second positioning block are also provided opposite to each other along the width direction of the hoisting main board;

[0029] During the descent of the main hoisting plate, the support frame is positioned between the first positioning block and the second positioning block, which improves the alignment accuracy of the main hoisting plate and thus enhances the precision of the hoisting operation.

[0030] In summary, this utility model has at least the following advantages:

[0031] 1. The present invention provides a hoisting fixture for energy storage modules, which improves the accuracy of energy storage module hoisting operations by setting protrusions for positioning energy storage modules on clamping components and setting limiting plates for limiting energy storage modules.

[0032] 2. The energy storage module hoisting fixture provided by this utility model, by setting a rotating support module, rotates the support plate to the lower end of the energy storage module, and then uses the first pin to lock the support plate to the connecting plate or the limiting plate, so that the support plate supports the lower end of the energy storage module, which helps to improve the stability of the energy storage module hoisting operation and thus improve the safety of the operation. Attached Figure Description

[0033] Figure 1 This is a schematic diagram of the structure of an energy storage module hoisting fixture provided in Embodiment 1 of this utility model;

[0034] Figure 2 This is a schematic diagram of the rotating support module provided in Embodiment 1 of this utility model;

[0035] Figure 3 This is a schematic diagram of the clamping drive assembly provided in Embodiment 2 of this utility model;

[0036] Figure 4 This is a schematic diagram of the clamping guide assembly provided in Embodiment 2 of this utility model;

[0037] Figure 5 This is a structural schematic diagram of an energy storage module hoisting fixture provided in Embodiment 3 of this utility model;

[0038] Figure 6 This is a schematic diagram of the support frame provided in Embodiment 3 of this utility model;

[0039] Marked in the image:

[0040] 100. Hoisting the motherboard;

[0041] 200. Clamping module; 210. Clamping drive assembly; 211. Drive component; 212. Connecting rod; 213. Connecting frame; 2131. Connecting main board; 2132. Connecting side plate; 220. Clamping component; 221. Protrusion; 230. Clamping guide assembly; 231. Guide rail; 232. Slider; 240. Second pin; 250. Check valve;

[0042] 300. Limit plate;

[0043] 400, Rotary support module; 410, Connecting plate; 411, First positioning hole; 420, Support plate; 421, Second positioning hole; 430, First pin;

[0044] 500. Support frame;

[0045] 600. Limiting block; 610. Guide ramp;

[0046] 700, First positioning block;

[0047] 800, Second positioning block. Detailed Implementation

[0048] To facilitate understanding of the present invention, a more comprehensive description will be given below in conjunction with the accompanying drawings and specific embodiments. The drawings illustrate preferred embodiments of the invention. However, the invention can be implemented in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided to provide a thorough and complete understanding of the disclosure of the invention.

[0049] It should be noted that when a component is said to be "fixed to" another component, it can be directly attached to the other component or there may be an intervening component. When a component is said to be "connected to" another component, it can be directly connected to the other component or there may be an intervening component.

[0050] In the description of this invention, it should be noted that the terms "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," and "outer," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings, or the orientation or positional relationship commonly used when the product of this invention is in use. They are only for the convenience of describing this invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this invention. In addition, the terms "first," "second," "third," etc., are only used to distinguish descriptions and should not be construed as indicating or implying relative importance.

[0051] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention pertains. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

[0052] Example 1:

[0053] Please see Figure 1 and Figure 2 This embodiment provides a hoisting fixture for energy storage modules. The hoisting fixture includes a hoisting main board 100, a clamping module 200 arranged opposite to each other along the length direction of the hoisting main board 100, a limiting plate 300 arranged opposite to each other along the width direction of the hoisting main board 100, and a rotating support module 400. The clamping module 200, the limiting plate 300, and the rotating support module 400 are all connected to the hoisting main board 100.

[0054] Specifically, there are two clamping modules 200, which are located at both ends of the length of the hoisting body and are used to clamp the energy storage module. The limiting plate 300 is used to limit the energy storage module in the width direction, and the rotating support module 400 is used to support the lower end of the energy storage module after rotation.

[0055] The clamping module 200 includes a clamping drive assembly 210 and a clamping member 220 connected to the drive end of the clamping drive assembly 210. The clamping drive assembly 210 drives the clamping member 220 to move toward the energy storage module, so that the clamping member 220 clamps the energy storage module. A protrusion 221 for positioning the energy storage module is formed on the clamping member 220. Understandably, a positioning hole for inserting the protrusion 221 is reserved on the energy storage module. Before hoisting the energy storage module, the clamping member 220 is driven to move toward the energy storage module by the clamping drive assembly 210, so that the protrusion 221 on the clamping member 220 is inserted into the positioning hole of the energy storage module.

[0056] The rotating support module 400 includes a connecting plate 410, a support plate 420, and a first pin 430. The upper end of the connecting plate 410 is fixedly connected to the hoisting main plate 100, and the lower end of the connecting plate 410 is rotatably connected to the support plate 420. The support plate 420 rotates to the lower end of the energy storage module, and the first pin 430 locks the support plate 420 onto the connecting plate 410 or the limiting plate 300.

[0057] Specifically, the connecting plate 410 and the limiting plate 300 are positioned opposite each other in the width direction of the energy storage module, limiting the energy storage module in the width direction. The support plate 420 and the connecting plate 410 are rotatably connected. It can be understood that before clamping the energy storage module, the support plate 420 is rotated around the connection point with the connecting plate 410 in a direction away from the limiting plate 300. After the energy storage module is limited between the connecting plate 410 and the limiting plate 300, and after the clamping module 200 has completed the clamping operation of the energy storage module, the support plate 420 is rotated around the connection point with the connecting plate 410 in a direction towards the limiting plate 300 until the support plate 420 is rotated to the lower end of the energy storage module. Then, the first pin 430 is used to lock the support plate 420 onto the connecting plate 410 or the limiting plate 300.

[0058] In some embodiments, a first positioning hole 411 is formed at the lower end of the connecting plate 410, and a second positioning hole 421 matching the first positioning hole 411 is formed on the support plate 420. After the support plate 420 is rotated to the lower end of the energy storage module, the first pin 430 is inserted into the first positioning hole 411 and the second positioning hole 421 to lock the support plate 420, so that the support plate 420 provides a stable support for the energy storage module and improves the stability and safety of the energy storage module hoisting operation.

[0059] When the energy storage module does not need to be hoisted, the support plate 420 is rotated away from the limiting plate 300 so that the support plate 420 is close to the connecting plate 410. Then, the first pin 430 is inserted into the first positioning hole 411 or the second positioning hole 421 for storage. A connecting block or the like can also be set at the rotating end of the support plate 420 to connect and fix the support plate 420 and the connecting plate 410, so as to prevent the support plate 420 from falling off due to its own weight around the rotating point and avoid affecting the subsequent hoisting and clamping operations.

[0060] This embodiment provides an energy storage module hoisting fixture. By setting a protrusion 221 for positioning the energy storage module on the clamping assembly and setting a limiting plate 300 for limiting the energy storage module, the accuracy of the energy storage module hoisting operation can be improved. By setting a rotating support module 400, after the support plate 420 is rotated to the lower end of the energy storage module, the support plate 420 is locked to the connecting plate 410 or the limiting plate 300 by the first pin 430, so that the support plate 420 supports the lower end of the energy storage module, which helps to improve the stability of the energy storage module hoisting operation and thus improves the safety of the operation.

[0061] Example 2:

[0062] This embodiment makes further structural optimizations based on Embodiment 1. Please refer to... Figures 1-2 Based on the above, refer to Figure 3 and Figure 4 .

[0063] In this embodiment, the clamping drive assembly 210 includes a drive member 211, a connecting rod 212, and a connecting frame 213. The two ends of the connecting rod 212 are respectively connected to the drive end of the drive member 211 and the connecting frame 213. Under the driving action of the drive member 211, the connecting rod 212 can move in conjunction with the connecting frame 213. The clamping member 220 is disposed on the connecting frame 213. The movement of the connecting frame 213 will drive the movement of the clamping member 220. That is, through the linkage between the connecting rod 212 and the connecting frame 213, the drive member 211 can indirectly drive the clamping movement of the clamping member 220 to achieve the clamping effect on the energy storage module.

[0064] The driving component 211 can be a power element such as a cylinder, electric cylinder, or quick clamp. The power element drives the clamping component 220 to move. For example, if the driving component 211 is a push-pull quick clamp, by pulling up the handle of the quick clamp, the clamping component 220 moves away from the energy storage module under the linkage of the connecting rod 212 and the connecting frame 213. Similarly, by pushing down the handle of the quick clamp, the clamping component 220 moves towards the energy storage module under the linkage of the connecting rod 212 and the connecting frame 213.

[0065] The connecting frame 213 includes a connecting main board 2131 and connecting side plates 2132 disposed on both sides of the connecting main board 2131; the hoisting main board 100 is located at the lower end of the connecting main board 2131 and between the two connecting side plates 2132; the clamping member 220 is disposed on the two connecting side plates 2132.

[0066] Specifically, there are two connecting side plates 2132, which are respectively set on both sides of the connecting main board 2131. The upper ends of the two connecting side plates 2132 are connected to both sides of the connecting main board 2131, and the lower ends of the two connecting side plates 2132 are connected to the clamping member 220, thereby improving the connection stability of the clamping member 220 and the uniformity of the force on the clamping member 220.

[0067] In some embodiments, the clamping module 200 further includes a clamping guide assembly 230; the clamping guide assembly 230 includes a guide rail 231 and a slider 232 that slides along the guide rail 231, the guide rail 231 being distributed along the driving direction of the drive member 211; the connecting frame 213 connects to the slider 232, and the stability of the clamping member 220 during the clamping motion is improved through the guiding sliding action of the guide rail 231 and the slider 232.

[0068] Specifically, the guide rail 231 is mounted on the hoisting main board 100 and distributed along the driving direction of the drive component 211. The slider 232 is slidably connected to the guide rail 231. The connecting frame 213 is connected to the slider 232. Under the driving action of the drive component 211, the connecting frame 213 drives the slider 232 to move along the guide rail 231. That is, the connecting frame 213 moves on the predetermined path of the guide rail 231, thereby driving the clamping component 220 to move stably.

[0069] The clamping module 200 also includes a second pin 240; the second pin 240 is used to lock the connecting frame 213 onto the hoisting main board 100 to prevent the clamping component 220 from moving after clamping the energy storage module, thereby improving the stability of the hoisting operation.

[0070] Multiple positioning holes are provided on the connecting frame 213 at the position relative to the hoisting motherboard 100, which can be used for the insertion of the second pin 240. After the clamping member 220 is moved into place by the driving member 211, the second pin 240 can be inserted into the positioning hole to lock the position of the connecting frame 213.

[0071] In some embodiments, the clamping module 200 further includes a check valve 250; the check valve 250 is located between the connecting main board 2131 and the hoisting main board 100 to prevent the clamping member 220 from moving after clamping the energy storage module, thereby improving the stability of the hoisting operation.

[0072] After the clamping member 220 is moved into place by the driving member 211, the state of the check member 250 can be switched to the check state, so that the upper end face of the check member 250 interferes with the lower end face of the connecting motherboard 2131, preventing the connecting bracket 213 from moving. When it is necessary to remove the energy storage module, the state of the check member 250 is switched to the non-check state, so that the upper end face of the check member 250 and the lower end face of the connecting motherboard 2131 will not interfere with each other.

[0073] This embodiment provides an energy storage module hoisting fixture, in which a second pin 240 is provided in the clamping module 200 to lock the connecting frame 213 to the hoisting main board 100, preventing the clamping member 220 from moving after clamping the energy storage module, thereby improving the stability of the hoisting operation; at the same time, a check piece 250 can also be provided to prevent the clamping member 220 from moving after clamping the energy storage module, thereby improving the stability of the hoisting operation.

[0074] Example 3:

[0075] This embodiment makes further structural optimizations based on Embodiment 1. Please refer to... Figures 1-4 Based on the above, refer to Figure 5 and Figure 6 .

[0076] In this embodiment, the energy storage module hoisting fixture also includes a support frame 500 that is arranged opposite to the hoisting main board 100 along its width direction; the support frame 500 is located below the hoisting main board 100 and is used to support the hoisting main board 100, improve the alignment accuracy of the hoisting main board 100, and thus improve the precision of the hoisting operation.

[0077] Before clamping and hoisting the energy storage module, the hoisting main board 100 needs to be lowered. Here, a support frame 500 is set to support the hoisting main board 100 so that the clamping module 200 can perform the clamping operation.

[0078] A limit block 600 is provided at the upper end of the support frame 500; a guide slope 610 is formed on the limit block 600, which is used to guide the main board 100 during descent.

[0079] During the descent of the hoisting main board 100, the lower end face of the hoisting main board 100 first contacts the guide ramp 610 on the limit block 600, and the hoisting main board 100 slides down the guide ramp 610 onto the support frame 500.

[0080] In some embodiments, the energy storage module hoisting fixture further includes a first positioning block 700 and a second positioning block 800 disposed opposite to each other along the width direction of the hoisting main board 100; during the descent of the hoisting main board 100, the support frame 500 is positioned between the first positioning block 700 and the second positioning block 800, so that the hoisting main board 100 can accurately slide down the guide ramp 610 onto the support frame 500, thereby improving the alignment accuracy of the hoisting main board 100 and thus improving the precision of the hoisting operation.

[0081] The above description is merely an example and illustration of the structure of this invention, and while the description is specific and detailed, it should not be construed as limiting the scope of this invention. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this invention, and these obvious substitutions all fall within the protection scope of this invention.

Claims

1. A hoisting fixture for an energy storage module, characterized in that, It includes a hoisting main board (100), a clamping module (200) arranged opposite to each other along the length direction of the hoisting main board (100), a limiting plate (300) arranged opposite to each other along the width direction of the hoisting main board (100), and a rotating support module (400). The clamping module (200), the limiting plate (300) and the rotating support module (400) are all connected to the hoisting main board (100). The clamping module (200) is used to clamp the energy storage module, the limiting plate (300) is used to limit the energy storage module, and the rotating support module (400) is used to support the lower end of the energy storage module. The clamping module (200) includes a clamping drive assembly (210) and a clamping member (220) connected to the drive end of the clamping drive assembly (210). The clamping member (220) has a protrusion (221) for positioning the energy storage module. The rotating support module (400) includes a connecting plate (410), a support plate (420), and a first pin (430). The upper end of the connecting plate (410) is fixedly connected to the hoisting main plate (100), and the lower end of the connecting plate (410) is rotatably connected to the support plate (420). The support plate (420) rotates to the lower end of the energy storage module, and the first pin (430) locks the support plate (420) onto the connecting plate (410) or the limiting plate (300).

2. The energy storage module hoisting fixture according to claim 1, characterized in that, The lower end of the connecting plate (410) is also formed with a first positioning hole (411), and the support plate (420) is formed with a second positioning hole (421) that matches the first positioning hole (411). After the support plate (420) is rotated to the lower end of the energy storage module, the first pin (430) is inserted into the first positioning hole (411) and the second positioning hole (421) to lock the support plate (420).

3. The energy storage module hoisting fixture according to claim 1, characterized in that, The clamping drive assembly (210) includes a drive component (211), a connecting rod (212), and a connecting frame (213). The two ends of the connecting rod (212) are respectively connected to the driving end of the driving member (211) and the connecting frame (213), and the clamping member (220) is disposed on the connecting frame (213).

4. The energy storage module hoisting fixture according to claim 3, characterized in that, The connecting frame (213) includes a connecting main board (2131) and connecting side plates (2132) disposed on both sides of the connecting main board (2131). The hoisting main plate (100) is located at the lower end of the connecting main plate (2131) and between the two connecting side plates (2132); The clamping element (220) is disposed on the connecting side plates (2132) on both sides.

5. The energy storage module hoisting fixture according to claim 3, characterized in that, The clamping module (200) also includes a clamping guide assembly (230); The clamping guide assembly (230) includes a guide rail (231) and a slider (232) that slides along the guide rail (231), the guide rail (231) being distributed along the driving direction of the drive member (211); The connecting frame (213) connects to the slider (232).

6. The energy storage module hoisting fixture according to claim 3, characterized in that, The clamping module (200) also includes a second pin (240); The second pin (240) is used to lock the connecting frame (213) onto the hoisting main plate (100).

7. The energy storage module hoisting fixture according to claim 4, characterized in that, The clamping module (200) also includes a check valve (250); The check valve (250) is located between the connecting main board (2131) and the hoisting main board (100) and is used to prevent the connection main board (2131) from turning back.

8. The hoisting fixture for the energy storage module according to any one of claims 1-7, characterized in that, It also includes a support frame (500) that is disposed opposite to the width direction of the main lifting plate (100). The support frame (500) is located below the hoisting main board (100) and is used to support the hoisting main board (100).

9. The energy storage module hoisting fixture according to claim 8, characterized in that, The upper end of the support frame (500) is provided with a limit block (600). A guide slope (610) is formed on the limiting block (600), and the guide slope (610) is used to guide the descent of the hoisting main board (100).

10. The energy storage module hoisting fixture according to claim 8, characterized in that, It also includes a first positioning block (700) and a second positioning block (800) that are disposed opposite to each other along the width direction of the hoisting main board (100); During the descent of the hoisting main board (100), the support frame (500) is positioned between the first positioning block (700) and the second positioning block (800).