A graphene lithium ion battery production handling device

By introducing clamping and lifting components into the graphene lithium-ion battery handling device, the problem of battery detachment during equipment failure or collision is solved, achieving stable and safe battery handling.

CN224464694UActive Publication Date: 2026-07-07HEFEI JIUYI SOFTWARE DEV CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HEFEI JIUYI SOFTWARE DEV CO LTD
Filing Date
2025-06-18
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing graphene lithium-ion battery handling devices have a high risk of battery detachment due to sudden decrease in clamping force during equipment failure or collisions, and cannot guarantee stability and safety.

Method used

A handling device including a clamping component and a lifting component is designed. The clamping component achieves stable clamping through a telescopic cylinder and a clamping plate, while the lifting component provides additional support in case of equipment failure or collision through the engagement of a lifting plate and a toothed block, preventing the battery from falling off.

Benefits of technology

It significantly improves the stability and safety of the handling process, prevents the battery from falling off in the event of equipment failure or collision, and protects the battery from damage.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to the technical field of battery production, concretely relates to a graphite alkene lithium ion battery production handling device, it includes, the mounting seat, the bottom of mounting seat is equipped with telescopic pneumatic cylinder, the telescopic pneumatic cylinder bottom is connected with clamping assembly, clamping assembly includes the bottom plate fixedly connected in telescopic pneumatic cylinder output end, the bottom of bottom plate is provided with clamping plate, clamping plate is used for clamping battery block, the bottom of bottom plate is provided with lifting assembly, lifting assembly includes the fixed plate fixedly connected in bottom plate bottom, the fixed plate is provided with no. The bottom of no. The lifting plate setting in the bottom of battery block is provided with lifting plate, lifting plate sets up in the bottom of battery block. The utility model can effectively solve the problem that the battery falls off in the prior art in the handling process, if the mobile equipment appears the breakdown or the collision with other equipment, leads to the clamping strength suddenly small, and the bottom does not support, leads to the problem.
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Description

Technical Field

[0001] This utility model relates to the field of storage battery production technology, specifically to a handling device for the production of graphene lithium-ion batteries. Background Technology

[0002] Graphene lithium-ion batteries are a new type of battery that combines the properties of graphene materials (such as high conductivity, high strength, and high thermal conductivity). Their production process demands high precision, cleanliness, and safety in material handling. Material handling equipment for graphene lithium-ion battery production is automated or semi-automated equipment specifically designed for this type of battery production process. It is used to achieve efficient and precise handling of materials (such as electrode sheets, cells, electrolytes, and battery modules) in each stage of production, while simultaneously meeting the specific requirements of graphene material properties and battery manufacturing processes.

[0003] In existing technologies, batteries are typically handled by clamping them on two or more sides. However, this clamping method relies solely on friction to overcome the battery's own weight. Therefore, during the entire handling process, a large force needs to be applied to the battery clamping side for an extended period to ensure stable clamping. However, this high-force clamping method can cause certain damage to the battery itself during transportation. Furthermore, if the mobile device malfunctions or collides with other equipment during handling, the clamping force may suddenly decrease, and without bottom support, the battery may fall off. Utility Model Content

[0004] In view of the above-mentioned shortcomings of the existing technology, the present invention provides a handling device for graphene lithium-ion battery production, which can effectively solve the problem that if the mobile device malfunctions or collides with other devices during the handling process, the clamping force will suddenly decrease and there will be no support at the bottom, resulting in the battery falling off.

[0005] To achieve the above objectives, this utility model provides the following technical solution:

[0006] This utility model provides a handling device for graphene lithium-ion battery production, including: a mounting base, a telescopic cylinder mounted on the bottom of the mounting base, a clamping assembly connected to the bottom of the telescopic cylinder, the clamping assembly including a base plate fixedly connected to the output end of the telescopic cylinder, a clamping plate provided at the bottom of the base plate for clamping battery blocks, and a lifting assembly provided at the bottom of the base plate.

[0007] The lifting assembly is used to lift the battery block. The lifting assembly includes a fixed plate fixedly connected to the bottom of the base plate. A second sliding plate is provided inside the fixed plate. A lifting plate is provided at the bottom of the second sliding plate. The lifting plate is located at the bottom of the battery block.

[0008] According to the above-mentioned conveying device for graphene lithium-ion battery production, a T-shaped groove is provided in the base plate, a lead screw is provided in the T-shaped groove, a T-shaped slider is provided on the side wall of the lead screw, the T-shaped slider is slidably connected in the T-shaped groove, a clamping plate is fixedly connected to the bottom of the T-shaped slider, and a sponge pad is fixedly connected to the side wall of the clamping plate.

[0009] The fixed plate has a drive groove, and a first slide plate and a second slide plate are slidably connected in the drive groove. The top of the first slide plate is fixedly connected to the bottom of the mounting base, and the first slide plate and the second slide plate are connected by a spring.

[0010] The bottom of the second slide is fixedly connected to an installation block, and a fixed shaft is fixedly connected to one side of the installation block. A support plate is rotatably connected to the outer wall of the fixed shaft.

[0011] The second slide plate has an inner groove, and a secondary drive rod is slidably connected in the inner groove. The secondary drive rod is fixedly connected to the bottom of the first slide plate.

[0012] The bottom of the secondary drive rod is fixedly connected to a first tooth block, which is meshed with a second tooth block, which is fixedly connected to one side of the lifting plate.

[0013] The technical solution provided by this utility model has the following advantages compared with the known prior art:

[0014] This invention controls the rotation and unfolding of the lifting plate by the lifting assembly during the retraction of the telescopic cylinder. The rigid engagement of the first and second tooth blocks allows the lifting plate to stably support the bottom of the battery. When equipment failure or collision causes a sudden decrease in clamping force, the lifting plate can immediately bear the weight of the battery, avoiding the risk of falling off and significantly improving the stability and safety of the handling process. Attached Figure Description

[0015] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0016] Figure 1 This is a three-dimensional structural diagram of the present invention;

[0017] Figure 2 This is a schematic cross-sectional view of the present invention.

[0018] Figure 3 This utility model Figure 2 Enlarged structural diagram at point A in the middle.

[0019] Reference numerals: 1. Mounting base; 2. Telescopic cylinder; 3. Clamping assembly; 31. Base plate; 32. T-shaped slide groove; 33. T-shaped slider; 34. Clamping plate; 35. Sponge pad; 36. Lead screw; 4. Battery block; 5. Lifting assembly; 51. Fixing plate; 52. Drive slide groove; 53. First slide plate; 54. Second slide plate; 55. Mounting block; 56. Fixing shaft; 57. Lifting plate; 58. Inner groove; 59. Secondary drive rod; 510. First toothed block; 511. Second toothed block; 512. Spring. Detailed Implementation

[0020] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some, not all, of the embodiments of this utility model. All other embodiments obtained by those skilled in the art based on the embodiments of this utility model without creative effort are within the scope of protection of this utility model.

[0021] The present invention will be further described below with reference to the embodiments.

[0022] Example: Refer to Figures 1 to 3 A handling device for graphene lithium-ion battery production includes: a mounting base 1, the top of which is provided with multiple sets of bolt holes, which are bolted to a robotic arm, and the handling process of battery blocks 4 is realized by controlling the robotic arm.

[0023] A telescopic cylinder 2 is installed at the bottom of the mounting base 1. The telescopic cylinder 2 is designed to control the initial movement of the battery block 4 after the clamping process is completed. A clamping assembly 3 is connected to the bottom of the telescopic cylinder 2. The clamping assembly 3 includes a base plate 31 fixedly connected to the output end of the telescopic cylinder 2. A clamping plate 34 is provided at the bottom of the base plate 31. The clamping plate 34 is used to clamp the battery block 4.

[0024] A T-shaped groove 32 is provided in the base plate 31. A lead screw 36 is provided in the T-shaped groove 32. A T-shaped slider 33 is provided on the side wall of the lead screw 36. The T-shaped slider 33 is slidably connected in the T-shaped groove 32. A clamping plate 34 is fixedly connected to the bottom of the T-shaped slider 33. A sponge pad 35 is fixedly connected to the side wall of the clamping plate 34.

[0025] The lead screw 36 rotates under the control of the motor. Through the rotation of the lead screw 36 and the restriction of the T-shaped slide 32, the clamping plate 34 clamps the battery block 4. The sponge pad 35 is designed to reduce the rigid contact between the battery block 4 and the clamping plate 34, thereby ensuring the stable transportation of the battery block 4 while maintaining the clean appearance of the battery block 4.

[0026] A support component 5 is provided at the bottom of the base plate 31;

[0027] The lifting assembly 5 is used to lift the battery block 4. The lifting assembly 5 includes a fixing plate 51 fixedly connected to the bottom of the base plate 31. A second sliding plate 54 is provided inside the fixing plate 51. A lifting plate 57 is provided at the bottom of the second sliding plate 54. The lifting plate 57 is located at the bottom of the battery block 4.

[0028] The lifting plate 57 bends and rotates to ensure support for the bottom of the battery block 4, preventing the battery block 4 from falling off.

[0029] The fixed plate 51 has a drive groove 52, and a first slide plate 53 and a second slide plate 54 are slidably connected in the drive groove 52. The top of the first slide plate 53 is fixedly connected to the bottom of the mounting base 1, and the first slide plate 53 and the second slide plate 54 are connected by a spring 512.

[0030] The bottom of the second skateboard 54 is fixedly connected to a mounting block 55, and a fixed shaft 56 is fixedly connected to one side of the mounting block 55. A support plate 57 is rotatably connected to the outer side wall of the fixed shaft 56.

[0031] The second slide plate 54 has an inner groove 58, and a secondary drive rod 59 is slidably connected in the inner groove 58. The secondary drive rod 59 is fixedly connected to the bottom of the first slide plate 53.

[0032] The bottom of the secondary drive rod 59 is fixedly connected to a first tooth block 510, which is meshed with a second tooth block 511. The second tooth block 511 is fixedly connected to one side of the lifting plate 57.

[0033] The meshing design of the first tooth block 510 and the second tooth block 511 ensures that the lifting plate 57 will not fail to support the battery block 4 when it is lifted. Compared with the elastic connection of the torsion spring, the rigid connection between the tooth blocks can ensure that the lifting plate 57 has enough force to support the battery block 4.

[0034] By adding a lifting component 5 to the bottom of the clamping component 3, a double protection structure is formed: when the telescopic cylinder 2 retracts, the lifting component 5 triggers the lifting plate 57 to rotate and unfold. Through the rigid meshing of the first tooth block 510 and the second tooth block 511, the lifting plate 57 stably supports the bottom of the battery block 4. When the clamping force is suddenly reduced due to equipment failure or collision, the lifting plate 57 can immediately bear the weight of the battery block 4, avoiding the risk of falling off and significantly improving the stability and safety of the handling process.

[0035] The working principle of this utility model is as follows:

[0036] In use, the clamping assembly 3 first clamps the battery block 4 by rotating the lead screw 36. After clamping, the telescopic cylinder 2 begins to retract. At this time, the base plate 31 begins to slide upward relative to the mounting base 1. At this time, the first slide plate 53, which is fixedly connected to the bottom of the mounting base 1, begins to slide downward relative to the base plate 31. Therefore, the second slide plate 54 and the lifting plate 57 connected to it begin to slide downward simultaneously (initially, the lifting plate 57 is in a vertical state). When the second slide plate 54 slides to the bottom of the drive groove 52, the first slide plate 53 continues to control the secondary drive rod 59, which is fixedly connected to it, to slide downward. Through the meshing of the first tooth block 510 and the second tooth block 511 at the bottom of the secondary drive rod 59, the lifting plate 57 begins to rotate when the secondary drive rod 59 slides downward. At this time, the lifting plate 57 begins to support the battery block 4, ensuring the stability of the battery block 4 during transportation.

[0037] The above embodiments are only used to illustrate the technical solutions of this utility model, and are not intended to limit it. Although this utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some of the technical features. Such modifications or substitutions will not cause the essence of the corresponding technical solutions to deviate from the protection scope of the technical solutions of the embodiments of this utility model.

Claims

1. A handling device for graphene lithium-ion battery production, characterized in that, Includes: a mounting base (1), a telescopic cylinder (2) is mounted on the bottom of the mounting base (1), a clamping assembly (3) is connected to the bottom of the telescopic cylinder (2), the clamping assembly (3) includes a base plate (31) fixedly connected to the output end of the telescopic cylinder (2), a clamping plate (34) is provided at the bottom of the base plate (31), the clamping plate (34) is used to clamp the battery block (4), and a lifting assembly (5) is provided at the bottom of the base plate (31); The lifting assembly (5) is used to lift the battery block (4). The lifting assembly (5) includes a fixing plate (51) fixedly connected to the bottom of the base plate (31). A second sliding plate (54) is provided inside the fixing plate (51). A lifting plate (57) is provided at the bottom of the second sliding plate (54). The lifting plate (57) is located at the bottom of the battery block (4).

2. The handling device for graphene lithium-ion battery production according to claim 1, characterized in that, The base plate (31) has a T-shaped groove (32) inside, a lead screw (36) is provided in the T-shaped groove (32), a T-shaped slider (33) is provided on the side wall of the lead screw (36), the T-shaped slider (33) is slidably connected in the T-shaped groove (32), a clamping plate (34) is fixedly connected to the bottom of the T-shaped slider (33), and a sponge pad (35) is fixedly connected to the side wall of the clamping plate (34).

3. The handling device for graphene lithium-ion battery production according to claim 1, characterized in that, The fixed plate (51) has a drive groove (52) inside, and a first slide plate (53) and a second slide plate (54) are slidably connected in the drive groove (52). The top of the first slide plate (53) is fixedly connected to the bottom of the mounting base (1), and the first slide plate (53) and the second slide plate (54) are connected by a spring (512).

4. The handling device for graphene lithium-ion battery production according to claim 1, characterized in that, The bottom of the second slide (54) is fixedly connected to an installation block (55), and a fixed shaft (56) is fixedly connected to one side of the installation block (55). A support plate (57) is rotatably connected to the outer side wall of the fixed shaft (56).

5. A handling device for graphene lithium-ion battery production according to claim 3, characterized in that, The second slide plate (54) has an inner groove (58) inside, and a secondary drive rod (59) is slidably connected inside the inner groove (58). The secondary drive rod (59) is fixedly connected to the bottom of the first slide plate (53).

6. A handling device for graphene lithium-ion battery production according to claim 5, characterized in that, The bottom of the secondary drive rod (59) is fixedly connected to a first tooth block (510), which is engaged with a second tooth block (511). The second tooth block (511) is fixedly connected to one side of the lifting plate (57).