A sleeve joint device with a size adjusting structure
By designing a socketing device with a size adjustment structure, the automated threading of wires and materials was achieved, solving the problems of low efficiency and poor accuracy of traditional manual operation, improving production efficiency and consistency, and adapting to diverse size requirements.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHENZHEN MINGYUANXIN WATERPROOF BOLT EQUIPMENT CO LTD
- Filing Date
- 2025-08-14
- Publication Date
- 2026-07-07
AI Technical Summary
Traditional manual operation is inefficient and inaccurate, while existing automated equipment lacks size adjustment capabilities, resulting in inaccurate alignment of wires and materials, which affects the success rate of threading and the versatility of the equipment.
Design a socketing device with a size adjustment structure, including a socketing structure and a size adjustment structure. Through the coordinated work of the feeding, rotating and assembly structures, the device can achieve automated threading of wires and materials, ensuring precise alignment and versatility.
It improves production efficiency and consistency, adapts to different specifications, reduces manual intervention, and enhances the reliability of wire and material threading and the versatility of equipment.
Smart Images

Figure CN224472907U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of automation technology, and specifically relates to a socket device with a size adjustment structure. Background Technology
[0002] In the fields of electronics, wire harnesses, medical devices, and precision manufacturing, it is often necessary to thread wires such as electrical wires, optical fibers, and conduits into materials such as sleeves, connectors, and sheaths. This process has the following drawbacks: Traditional manual operation has limitations; manual threading is inefficient and prone to errors such as wire bending, misalignment, or material damage, affecting product quality. For mass production, manual methods cannot guarantee consistency, increasing production costs. Existing automated equipment has shortcomings; some automated equipment can only fix the size of wires and materials, lacking size adjustment capabilities, resulting in poor equipment versatility. Existing feeding, rotating, and assembly mechanisms may lack coordination, leading to inaccurate wire and material alignment, affecting the success rate of threading. Some equipment relies on a single drive method, limiting adjustment accuracy and flexibility. Utility Model Content
[0003] To address the aforementioned problems, the primary objective of this utility model is to provide a socketing device with a size adjustment structure, which solves the technical problems of inefficiency and low precision in traditional manual or semi-automatic threading methods.
[0004] To achieve the above objectives, the technical solution of this utility model is as follows:
[0005] This utility model provides a socket device with a size adjustment structure, comprising: a socket structure and a size adjustment structure, wherein the size adjustment structure is used to provide wire to the socket structure and to adjust the distance of the wire relative to the socket structure, and the socket structure is used to provide material to the size adjustment structure so as to thread the wire through the material.
[0006] This socketing device with a size adjustment structure provides wire to the socketing structure and adjusts the distance between the wire and the socketing structure. It also provides material to the size adjustment structure through the socketing structure, so as to thread the wire through the material. This achieves automated threading of wire and material, solves the problems of low efficiency and poor accuracy of traditional manual operation, and improves production efficiency and consistency.
[0007] Furthermore, the socket structure includes: a feeding structure, a rotating structure, and an assembly structure; wherein,
[0008] The rotating structure is disposed between the feeding structure and the assembly structure; the size adjustment structure is disposed on the side of the assembly structure away from the rotating structure.
[0009] The size adjustment structure is used to clamp the wire and provide the wire to the assembly structure; the feeding structure is used to provide the material to the rotating structure and press the material down at the first pressing position; the rotating structure is used to drive the material to rotate and to drive the material to move relative to the assembly structure so as to pass the wire through the material within the assembly structure.
[0010] By refining the socket structure into a feeding structure, a rotating structure, and an assembly structure, the division of labor among the modules is clearly defined. The feeding structure accurately supplies materials; the rotating structure enables the rotation and displacement of materials; and the assembly structure and the size adjustment structure work together to complete the wire threading, thereby optimizing the overall process flow and ensuring the alignment accuracy and threading reliability of the wire and materials.
[0011] Furthermore, the feeding structure includes:
[0012] The feeding structure includes:
[0013] A silo is used to supply materials;
[0014] The first gripper assembly is disposed on the side of the hopper near the rotating structure;
[0015] The first pressing element is located on the side of the hopper away from the rotating structure;
[0016] The first pressing member is used to press the material in the hopper onto the first claw assembly; the first claw assembly is used to transfer the material configured by the first pressing member to the rotating structure.
[0017] Furthermore, the feeding structure also includes:
[0018] A first drive component is connected to the first pressing member and is used to drive the first pressing member to press the material in the hopper toward the first claw cylinder.
[0019] A first gripper cylinder is connected to the first gripper assembly and is used to drive the first gripper assembly to clamp or release the material.
[0020] The second drive component, connected to the first gripper component, is used to drive the first gripper component to move toward the rotating structure to transfer the material from the first gripper component to the rotating structure.
[0021] Furthermore, the rotating structure includes:
[0022] The second pressing element is used to move the material from the first rotational position to the second rotational position;
[0023] A rotary table is disposed between the feeding structure and the assembly structure, and the second pressing member is disposed on the rotary table.
[0024] Furthermore, the rotating structure also includes:
[0025] The second drive assembly includes a second cylinder, a second push rod, a rack, and a gear. The second push rod is connected between the second cylinder and the rack. The rack meshes with the gear, and the gear is connected to the rotary table. The second cylinder is used to drive the rotary table to rotate so that the second pressing member is located between the first rotation position and the second rotation position.
[0026] The third drive assembly, connected to the rotary table, is used to drive the rotary table to move back and forth so that the second pressing member can drive the material to be positioned on the outer peripheral surface of the wire.
[0027] The rotary table and the second pressing component enable multi-station material transfer to adapt to the needs of different processing stages. The second drive component provides stable rotational power, and the third drive component enables axial movement of the material, ensuring precise alignment and assembly of the wire and the material.
[0028] Furthermore, the assembly structure includes:
[0029] Two mating blocks are spaced apart between the rotary table and the size adjustment structure; wherein,
[0030] The two mating blocks are joined together to form a mating groove for configuring the material; the mating block is provided with a through hole and an extension groove on the side near the rotating structure; the mating block is provided with a through hole and an arc-shaped groove on the side near the size adjustment structure.
[0031] The arc-shaped groove, the insertion hole, the mating groove, the extension groove, and the material insertion hole are arranged coaxially in sequence.
[0032] Furthermore, the assembly structure also includes:
[0033] The fourth drive component, connected to the mating blocks, is used to drive the two mating blocks to move toward or away from the size adjustment structure.
[0034] Furthermore, the arc-shaped groove and the wire insertion hole are sequentially formed from the side surface of the mating block near the size adjustment structure toward the interior of the mating block; the material passage hole and the extension groove are sequentially formed from the side surface of the mating block near the rotating structure toward the interior of the mating block.
[0035] The coaxial channel is formed by the arc groove, insertion hole, mating groove, extension groove and material passage hole to ensure straight alignment of material and wire; the fourth drive component controls the back and forth movement of the mating block to enhance the versatility of the device.
[0036] Furthermore, the size adjustment structure includes:
[0037] The second claw assembly is used to clamp or release the wire so that the wire passes through the material;
[0038] The second gripper cylinder is connected to the first gripper assembly and is used to drive the first gripper assembly to lock or release.
[0039] The fifth drive component is connected to the first gripper component and is used to drive the first gripper component to move back and forth.
[0040] Furthermore, the fifth driving component includes:
[0041] Electric motor;
[0042] The slider connects to the output shaft of the motor;
[0043] A conveyor belt, connected to the slider, is used to drive the slider to move back and forth; wherein,
[0044] The second gripper cylinder and the second gripper assembly are disposed on the slider.
[0045] The wire is clamped / released by the second claw assembly and the second claw cylinder to prevent wire deviation; the length of the wire extending into the material is precisely adjusted by the fifth drive assembly to meet diverse size requirements and improve product adaptability.
[0046] Compared with existing technologies, the beneficial effects of this application are as follows: The socket device with a size adjustment structure includes a socket structure and a size adjustment structure. The size adjustment structure is used to provide wire to the socket structure and adjust the distance between the wire and the socket structure. The socket structure is used to provide material to the size adjustment structure to thread the wire through the material. This socket device with a size adjustment structure automatically threads the wire through the material, solving the problems of low efficiency and poor accuracy of traditional manual operation, and improving production efficiency. Attached Figure Description
[0047] Figure 1 This is a schematic diagram of the sleeve device with a size adjustment structure according to the present invention.
[0048] Figure 2 This is a partial structural schematic diagram of the socket device with a size adjustment structure according to this utility model.
[0049] Figure 3 This is a schematic diagram of the assembly structure of the sleeve device with size adjustment structure of this utility model.
[0050] In the diagram: 10. Feeding structure; 11. Hopper; 12. First gripper assembly; 13. First pressing component; 14. First drive assembly; 15. First gripper cylinder; 16. Second drive assembly; 20. Rotating structure; 21. Second pressing component; 22. Rotary table; 23. Second drive assembly; 231. Second cylinder; 232. Second push rod; 233. Gear; 234. Rack; 24. Third drive assembly; 30. Assembly structure; 31. Mating block; 311. Mating groove; 312. Material through hole; 313. Extension groove; 314. Wire insertion hole; 315. Arc groove; 32. Fourth drive assembly; 40. Size adjustment structure; 41. Second gripper assembly; 42. Second gripper cylinder; 43. Fifth drive assembly; 431. Motor; 432. Slider; 433. Conveyor belt. Detailed Implementation
[0051] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present utility model and are not intended to limit the present utility model.
[0052] It should be noted that when performing high-precision threading, firstly, it is necessary to ensure the coaxiality of the wire and the material to avoid threading failure or damage to the product. Secondly, the wire size must be adjustable to accommodate wires and materials of different diameters, improving the applicability of the equipment. Furthermore, it must meet the requirements of automated collaboration, with modules such as feeding, rotation, assembly, and adjustment working seamlessly to reduce manual intervention. Finally, it must meet the requirements of intelligent detection and feedback to ensure accurate material supply and positioning.
[0053] To achieve the above objectives, the technical solution of this utility model is as follows:
[0054] See Figures 1-3 As shown, this utility model provides a socket device with a size adjustment structure, and more particularly provides a waterproof plug socket device with a size adjustment structure, including: a socket structure and a size adjustment structure 40. The size adjustment structure 40 is used to provide wire to the socket structure and to adjust the distance between the wire and the socket structure. The socket structure is used to provide material to the size adjustment structure 40 so that the wire is threaded through the material.
[0055] This socketing device with a size adjustment structure provides wire to the socketing structure via the size adjustment structure 40 and adjusts the distance between the wire and the socketing structure. The socketing structure provides material to the size adjustment structure 40, allowing the wire to be threaded through the material. This achieves automated wire-to-material threading, solving the problems of low efficiency and poor accuracy associated with traditional manual operation, and improving production efficiency and consistency. The size adjustment structure 40 dynamically controls the distance the wire extends into the material, adapting to different specification requirements.
[0056] Furthermore, the socket structure includes: a feeding structure 10, a rotating structure 20, and an assembly structure 30; wherein, the rotating structure 20 is disposed between the feeding structure 10 and the assembly structure 30; the size adjustment structure 40 is disposed on the side of the assembly structure 30 away from the rotating structure 20; the size adjustment structure 40 is used to clamp the wire and provide the wire to the assembly structure 30; the feeding structure 10 is used to provide material to the rotating structure 20 and press the material down at the first pressing position; the rotating structure 20 is used to drive the material to rotate and to drive the material to move relative to the assembly structure 30, so as to thread the wire through the material within the assembly structure 30.
[0057] By subdividing the socket structure into a feeding structure 10, a rotating structure 20, and an assembly structure 30, the division of labor among the modules is clearly defined. The feeding structure 10 accurately supplies materials; the rotating structure 20 realizes the rotation and displacement of materials; and the assembly structure 30 and the size adjustment structure 40 work together to complete the wire threading, thereby optimizing the overall process flow and ensuring the alignment accuracy and threading reliability of the wire and materials.
[0058] Furthermore, the feeding structure includes: a hopper 11 for providing materials; a first claw assembly 12 disposed on the side of the hopper 11 close to the rotating structure 20; and a first pressing member 13 disposed on the side of the hopper 11 away from the rotating structure 20. The first pressing member 13 is used to press the material in the hopper 11 onto the first claw assembly 12. The first claw assembly 12 is used to transfer the material disposed on the first pressing member 13 to the rotating structure 20.
[0059] Furthermore, the feeding structure 10 also includes: a first drive assembly 14, a first gripper cylinder 15, and a second drive assembly 16; the first drive assembly 14 is connected to a first pressing member 13 and is used to drive the first pressing member 13 to press the material in the hopper 11 toward the first gripper assembly 12; the first gripper cylinder 15 is connected to the first gripper assembly 12 and is used to drive the first gripper assembly 12 to clamp or release the material; the second drive assembly 16 is connected to the first gripper assembly 12 and is used to drive the first gripper assembly 12 to move toward the rotating structure 20 to transfer the material of the first gripper assembly 12 to the rotating structure 20.
[0060] Two-stage feeding is achieved through the first gripper assembly 12 and the first pressing member 13: the first pressing member 13 pushes the material to the first gripper assembly 12, and the first gripper assembly 12 transfers the material to the rotating structure 20, preventing the material from falling or shifting. Furthermore, the stroke of the first pressing member 13 is controlled by the first drive assembly 14, and the movement of the first gripper assembly 12 relative to the rotating structure 20 is controlled by the second drive assembly 16, achieving high-precision material delivery. Additionally, the first gripper cylinder 15 ensures stable clamping of the material, adapting to fragile or flexible materials.
[0061] Furthermore, the rotating structure 20 includes: a second pressing member 21, used to drive the material to transfer from the first rotating position to the second rotating position; a rotating table 22, disposed between the feeding structure 10 and the assembly structure 30, and the second pressing member 21 is disposed on the rotating table 22.
[0062] Furthermore, the rotating structure 20 also includes: a second drive assembly 23, including a second cylinder 231, a second push rod 232, a rack 233, and a gear 234. The second push rod 232 is connected between the second cylinder 231 and the rack 233. The rack 233 meshes with the gear 234, and the gear 234 is connected to the rotating table 22. The second cylinder 231 is used to drive the rotating table 22 to rotate so that the second pressing member 21 is located between the first rotating position and the second rotating position. A third drive assembly 24 is connected to the rotating table 22 and is used to drive the rotating table 22 to move back and forth so that the second pressing member 21 can drive the material to be placed on the outer peripheral surface of the wire.
[0063] The rotary table 22 and the second pressing component 21 enable multi-station material transfer to meet the needs of different processing stages. The second drive assembly 23 provides stable rotational power, and the third drive assembly 24 enables axial movement of the material, ensuring precise alignment and assembly of the wire and the material.
[0064] The rotary table 22 and the second pressing component 21 enable multi-station material transfer from the first rotational position to the second rotational position. Stable rotational power is provided by the gear 234, rack 233, and second cylinder 231, resulting in high positioning accuracy and low noise. The third drive assembly 24 pushes the rotary table 22 axially back and forth, automatically aligning the material with the wire and preventing misalignment during threading.
[0065] Furthermore, the assembly structure 30 includes: two mating blocks 31, spaced apart between the rotating structure 20 and the size adjustment structure 40; wherein, the two mating blocks 31 enclose a mating groove 311 for dispensing materials; the mating block 31 has a through hole 312 and an extension groove 313 connected on the side near the rotating structure 20; the mating block 31 has a wire insertion hole 314 and an arc-shaped groove 315 connected on the side near the size adjustment structure 40; the arc-shaped groove 315, the wire insertion hole 314, the mating groove 311, the extension groove 313 and the through hole 312 are arranged coaxially in sequence.
[0066] Furthermore, the assembly structure 30 also includes a fourth drive component 32, which connects to the mating blocks 31 and is used to drive the two mating blocks 31 to move toward or away from the size adjustment structure 40.
[0067] Furthermore, an arc-shaped groove 315 and a wire insertion hole 314 are sequentially formed by recessing the surface of the self-fitting block 31 towards the interior of the self-fitting block 31 near the size adjustment structure 40; a material passage hole 312 and an extension groove 313 are sequentially formed by recessing the surface of the self-fitting block 31 towards the interior of the self-fitting block 31 near the rotating structure 20.
[0068] The coaxial channel design of the mating block 31, namely the arc groove 315, the insertion hole 314, the mating groove 311, the extension groove 313, and the material passage hole 312, is coaxially and sequentially arranged to ensure that the material and the wire are aligned coaxially throughout the process, reducing frictional resistance and protecting the surface of the wire. The fourth drive component 32 controls the back-and-forth movement of the mating block 31 to adapt to different distance dimensions of the wire and the material, making it highly versatile. The material configured by the second pressing component 21 is pressed forward by the two mating blocks 31, causing the two mating blocks 31 to move away from each other so that the material is positioned in the mating groove 311. Then, the material is assembled with the wire in the mating groove 311, that is, the outer peripheral surface of the wire is positioned on the inner peripheral surface of the material in the mating groove 311, thereby realizing the material passage stage of the wire.
[0069] Furthermore, the size adjustment structure 40 includes: a second gripper assembly 41, a second gripper cylinder 42, and a fifth drive assembly 43; wherein, the second gripper assembly 41 is used to clamp or release the wire so that the wire is threaded through the material; the second gripper cylinder 42 is connected to the gripper assembly 41 and is used to drive the second gripper assembly 41 to lock or release; the fifth drive assembly 43 is connected to the second gripper assembly 41 and is used to drive the second gripper assembly 41 to move back and forth.
[0070] Furthermore, the fifth drive assembly 43 includes: a motor 431; a slider 432 connected to the output shaft of the motor 431; a conveyor belt 4332 connected to the slider 432 and used to drive the slider 432 to move back and forth; wherein, the second gripper cylinder 42 and the second gripper assembly 41 are disposed on the slider 432.
[0071] The second gripper cylinder 42 drives the second gripper assembly 41 to clamp / release the wire. The second gripper assembly 41 can firmly clamp the wire, preventing it from shifting and slipping or bending when threading it through materials. By designing the fifth drive assembly 43 as a motor 431, slider 432, and conveyor belt 433, the insertion length of the wire relative to the material can be precisely adjusted to meet diverse size requirements, improve product adaptability, and achieve millimeter-level assembly accuracy between the wire and the material, meeting customized needs. In addition, the size adjustment structure 40 and the assembly structure 30 work together to achieve fully automatic threading between the wire and the material.
[0072] The usage process of the socket device with size adjustment structure described in this application is as follows:
[0073] 1. Initial preparation stage:
[0074] Load the materials to be threaded, such as sleeves and sheaths, into the hopper 11; pre-load the wires, such as electrical wires and optical fibers, into the second claw assembly 41; adjust the parameters of each drive assembly and set the required wire threading length.
[0075] 2. Material Supply Stage
[0076] The first drive assembly 14 pushes the first pressing member 13 to push out the single material at the bottom of the hopper 11; the material is pushed to the position of the first claw assembly 12; the first claw cylinder 15 is activated to make the first claw assembly 12 clamp the material; the second drive assembly 16 drives the first claw assembly 12 to move and transfer the material to the rotating structure 20.
[0077] 3. Material positioning stage:
[0078] The second cylinder 231 of the rotating structure 20 drives the rotating table 22 to rotate through the meshing of gear 233 and rack 234; the material rotates with the rotating table 22 from the first rotating position to the second rotating position, wherein the first rotating position is used as the receiving station and the second rotating position is used as the assembly station; the third drive assembly 24 pushes the rotating table 22 forward, and the rotating table 22 pushes the material forward, so that the material configured by the second pressing member 21 enters the mating groove 311 of the assembly structure 30;
[0079] 4. Cable adjustment stage:
[0080] The fifth drive component 43 drives the second claw component 41 to move forward; the front end of the wire passes through the insertion hole 314 of the assembly structure 30; the second claw cylinder 42 controls the second claw component 41 to release the wire.
[0081] 5. Installation and assembly stage:
[0082] The two mating blocks 31 close to form a complete threading channel; the rotating table 22 continues to push forward, so that the material is completely fitted onto the outside of the wire; the arc-shaped groove 315 and the extended groove 313 of the mating block 31 ensure a smooth threading process.
[0083] 6. Reset Phase:
[0084] Each drive component is reset in sequence: the rotary table 22 retracts and rotates back to the first rotation position; the mating block 31 opens; the first claw assembly 12 and the second claw assembly 41 retract to their initial positions; the finished product is taken out; the system prepares for the next work cycle.
[0085] Therefore, the present invention provides a socketing device with a size adjustment structure. By moving the mating block 31 back and forth relative to the second claw assembly 41, and by having the mating block 31 and the second claw assembly 41 respectively clamp both ends of the wire, the length of the wire can be adjusted. Thus, when the socketing device threads the wire into the material to form a product, it can be compatible with multiple product specifications. The entire process of feeding, rotating, threading, and resetting requires no manual intervention, significantly improving efficiency and being several times faster than manual operation. It can meet the needs of automated production with high precision, high efficiency, and multi-size adaptability. Furthermore, the first pressing member 13, the first claw assembly 12, and the second pressing member 21 located in the first rotation position are designed coaxially along the vertical axis, and the flexible clamping of the material by the first claw assembly 12 can reduce material damage. Additionally, the second pressing member 21 located in the second rotation position, the material disposed on the second pressing member 21, the material insertion hole 312, the extension groove 313, the mating groove 311, the insertion hole 314, the arc groove 315 of the assembly structure 30, and the wire clamped by the second claw assembly 41 are designed coaxially along the horizontal axis, and the flexible clamping of the wire by the second claw assembly 41 can reduce wire damage. This socket device with a size adjustment structure is suitable for electronic manufacturing such as cable assembly and connector processing, medical device such as catheters and endoscopes for wire threading, automotive wiring harnesses such as automated assembly of multi-specification wires and sheaths, and precision machinery such as applications requiring high-precision alignment for wire threading.
[0086] 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, and improvements 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 socket device with a size adjustment structure, characterized in that, include: A socket structure and a size adjustment structure are provided, wherein the size adjustment structure is used to provide wire to the socket structure and to adjust the distance of the wire relative to the socket structure, and the socket structure is used to provide material to the size adjustment structure so as to pass the wire through the material.
2. The sleeve device with a size adjustment structure as described in claim 1, characterized in that, The socket structure includes: a feeding structure, a rotating structure, and an assembly structure; wherein... The rotating structure is disposed between the feeding structure and the assembly structure; the size adjustment structure is disposed on the side of the assembly structure away from the rotating structure. The size adjustment structure is used to clamp the wire and provide the wire to the assembly structure; the feeding structure is used to provide the material to the rotating structure and press the material down at the first pressing position; the rotating structure is used to drive the material to rotate and to drive the material to move relative to the assembly structure so as to pass the wire through the material within the assembly structure.
3. The sleeve device with a size adjustment structure as described in claim 2, characterized in that, The feeding structure includes: A silo is used to supply materials; The first claw assembly is disposed on the side of the hopper near the rotating structure; The first pressing element is located on the side of the hopper away from the rotating structure; The first pressing member is used to press the material in the hopper onto the first claw assembly; the first claw assembly is used to transfer the material configured by the first pressing member to the rotating structure.
4. The sleeve device with a size adjustment structure as described in claim 3, characterized in that, The feeding structure further includes: A first gripper cylinder is connected to the first gripper assembly and is used to drive the first gripper assembly to clamp or release the material. A first drive component is connected to the first pressing member and is used to drive the first pressing member to press the material in the hopper toward the first claw cylinder. The second drive component, connected to the first gripper component, is used to drive the first gripper component to move toward the rotating structure to transfer the material from the first gripper component to the rotating structure.
5. A sleeve device with a size adjustment structure as described in claim 2, characterized in that, The rotating structure includes: The second pressing element is used to move the material from the first rotational position to the second rotational position; A rotary table is disposed between the feeding structure and the assembly structure, and the second pressing member is disposed on the rotary table.
6. A sleeve device with a size adjustment structure as described in claim 5, characterized in that, The rotating structure further includes: The second drive assembly includes a second cylinder, a second push rod, a rack, and a gear. The second push rod is connected between the second cylinder and the rack. The rack meshes with the gear, and the gear is connected to the rotary table. The second cylinder is used to drive the rotary table to rotate so that the second pressing member is located between the first rotation position and the second rotation position. The third drive assembly, connected to the rotary table, is used to drive the rotary table to move back and forth so that the second pressing member can drive the material to be positioned on the outer peripheral surface of the wire.
7. A sleeve device with a size adjustment structure as described in claim 2, characterized in that, The assembly structure includes: Two mating blocks are spaced apart between the rotating structure and the size adjustment structure; wherein, The two mating blocks are joined together to form a mating groove for configuring the material; the mating block is provided with a through hole and an extension groove on the side near the rotating structure; the mating block is provided with a through hole and an arc-shaped groove on the side near the size adjustment structure. The arc-shaped groove, the insertion hole, the mating groove, the extension groove, and the material insertion hole are arranged coaxially in sequence.
8. A sleeve device with a size adjustment structure as described in claim 7, characterized in that, The assembly structure also includes: The fourth drive component, connected to the mating blocks, is used to drive the two mating blocks to move toward or away from the size adjustment structure.
9. A sleeve device with a size adjustment structure as described in claim 2, characterized in that, The size adjustment structure includes: The second claw assembly is used to clamp or release the wire so that the wire passes through the material; The second claw cylinder is connected to the second claw assembly and is used to drive the second claw assembly to lock or release. The fifth drive component is connected to the second claw component and is used to drive the second claw component to move back and forth.
10. A sleeve device with a size adjustment structure as described in claim 9, characterized in that, The fifth driving component includes: Electric motor; The slider connects to the output shaft of the motor; A conveyor belt, connected to the slider, is used to drive the slider to move back and forth; wherein, The second gripper cylinder and the second gripper assembly are disposed on the slider.