Material transfer device for production of teflon wire
By incorporating support components and clamping structures in the transfer device, the problems of scratches and insulation damage caused by friction during the transfer of Teflon wires are solved, achieving stable positioning and protection of the wires and improving the quality and safety of the transfer process.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Filing Date
- 2025-06-16
- Publication Date
- 2026-07-07
AI Technical Summary
During the transfer of Teflon wires, friction between the wires and the inner wall of the transfer box can cause scratches and damage to the insulation layer. At the same time, bending or deformation may occur, affecting the quality and stability of the wires.
Design a transfer device with internal support components and clamping plate structure. The clamping plate squeezes and positions the wire on both sides to avoid direct contact with the transfer box. The slider and spring system stabilizes the position of the wire to ensure that the wire does not bend when it shakes.
It effectively reduces friction damage, maintains conductor stability, prevents insulation layer damage and deformation, and improves conductor quality and safety during transportation.
Smart Images

Figure CN224466432U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of Teflon wire production technology, specifically a material transfer device for Teflon wire production. Background Technology
[0002] The core function of Teflon wires is to transmit electrical energy. It transfers electrical energy from the power source to the load device through an internal metallic conductor (such as copper or copper alloy). Its insulation layer ensures that electrical energy does not leak during transmission and prevents electrical short circuits between the conductor and the external environment. Through its unique material properties and structural design, Teflon wires play a crucial role in power transmission, signal transmission, electrical insulation, mechanical protection, environmental adaptability, flame retardant safety, and high-frequency signal transmission.
[0003] After the Teflon wires are manufactured, they need to be rotated to move them during warehousing and logistics. However, because Teflon wires are soft, they may collide or rub against the transport box during transport, resulting in scratches on the surface of the Teflon wires and damage to the insulation layer, affecting the quality of the wires. Furthermore, friction can cause the wires to bend or deform due to external forces. Utility Model Content
[0004] The purpose of this utility model is to provide a material transfer device for the production of Teflon wires, so as to solve the problem mentioned in the background art that when transferring Teflon wires, the Teflon wires will rub against the inner wall of the transfer box, resulting in scratches on the surface of the wires and even damage to the insulation layer of the wires, affecting the appearance quality and overall strength of the wires. Furthermore, friction can also cause the wires to bend or deform.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a material transfer device for the production of Teflon wires, comprising a transfer box, wherein the transfer box is provided with a support assembly for positioning the Teflon wires during transfer, the support assembly includes multiple sliding grooves disposed on both sides of the inner wall of the transfer box, each of the multiple sliding grooves is provided with a support plate, a slider is disposed inside the sliding groove, a sleeve is disposed inside the slider, a spring and a connecting rod are disposed on the inner wall of the sleeve, and a clamping plate is disposed at the other end of the connecting rod;
[0006] The clamping plate is provided with an installation frame at the top. Inside the installation frame of one side of the clamping plate in the transfer box, there is a winding roller. Inside the winding roller, there is a connecting rope. At the other end of the connecting rope, there is a locking block. Inside the installation frame of the other side of the clamping plate in the transfer box, there is a gear. Inside the gear, there is a connecting shaft. Inside the connecting shaft, there is a lead screw.
[0007] Preferably, multiple chute arrays are distributed inside the transfer box, and the chute angles on both sides of the inner wall of the transfer box correspond. The support plate has an arc-shaped structure at one end and an inclined angle at the other end, and is connected to the inner wall of the chute by bolts. The inclined angle of the support plate, combined with its own toughness, can push the slider to slide to the center position of the chute.
[0008] Preferably, the slider is located in the groove and is slidably connected to the inner wall of the groove. The sleeve is embedded in the slider. The two ends of the spring are respectively connected to the inner wall of the sleeve and the connecting rod. One end of the connecting rod is located in the sleeve and is slidably connected to the inner wall of the sleeve, and the other end extends to the outside and is connected to the clamping plate.
[0009] Preferably, the mounting frame is integrally formed with the top of the clamping plate, and the winding roller is located in the mounting frame in one side of the clamping plate inside the transfer box, and is rotatably connected to the inner wall of the mounting frame through a spring shaft.
[0010] Preferably, one end of the connecting rope is wound inside the take-up roller, and the other end is connected to the locking block. One end of the locking block is embedded into the mounting frame by pulling up the connecting rope through the take-up roller.
[0011] Preferably, the gear is located in the mounting frame at the top of the clamping plate on the other side of the transfer box, and the connecting shaft passes through the gear and is rotatably connected to the inner wall of the mounting frame. One end of the lead screw is embedded in the connecting shaft and is rotatably connected to the connecting shaft.
[0012] Compared with the prior art, the beneficial effects of this utility model are:
[0013] 1. By installing clamps on both sides inside the transfer box, when the Teflon wire is placed inside the transfer box, the clamps are positioned on both sides of the wire. Pulling the clamps close together compresses the wire. At the same time, the locking blocks in the mounting frames on the top of the clamps are inserted into the mounting frames on the other side of the clamps. The connecting shaft drives the gear to rotate, causing the locking blocks to rotate with the gear and winding up the connecting rope. This ensures that the clamps on both sides maintain the compressive force on the wire. The clamps prevent the wire from directly contacting the transfer box, effectively reducing friction and maintaining the stability of the wire during transfer.
[0014] 2. When the transfer box shakes during transportation, the clamps are connected to the wires. During the shaking, the slider outside the clamps can slide between the transfer box and the wires, thereby causing the wires to move along with it. The clamps also hold the wires in multiple places, ensuring the stability of the wire placement structure and preventing the wires from bending.
[0015] This invention clamps the Teflon wire during transport, preventing it from contacting and rubbing against the transport box. This improves the stability of the wire, supports and protects it from damage, and maintains the position and angle of the wire when it shakes during transport. This effectively reduces the possibility of bending or deformation of the wire, and improves the stability and quality of wire transport. Attached Figure Description
[0016] Figure 1 This is an overall isometric view of the present invention;
[0017] Figure 2 This is an enlarged view of part A of this utility model;
[0018] Figure 3 This is a structural diagram of the slider and clamping plate of this utility model.
[0019] Figure 4 This is a top sectional view of the mounting frame of one side of the clamping plate of this utility model;
[0020] Figure 5 This is an enlarged view of part B of this utility model.
[0021] In the diagram: 1. Transfer box; 2. Slide groove; 201. Support plate; 3. Slider; 4. Sleeve; 401. Spring; 402. Connecting rod; 5. Clamping plate; 6. Mounting frame; 7. Winding roller; 701. Connecting rope; 702. Clamping block; 8. Gear; 9. Connecting shaft; 901. Lead screw. Detailed Implementation
[0022] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0023] All devices in this application adopt conventional models in the prior art, and the control method is through a controller. The control circuit of the controller can be implemented by simple programming by those skilled in the art, which is common knowledge in the field, so this application will not explain it in detail.
[0024] Please see the appendix Figure 1-3As shown, a material transfer device for the production of Teflon wires includes a transfer box 1. The transfer box 1 contains a support assembly for positioning the Teflon wires during transfer. The support assembly includes multiple grooves 2 located on both sides of the inner wall of the transfer box 1 to position the sliding angle of a slider 3. Each groove 2 has a support plate 201 on its inner wall. The support plate 201, through its own toughness and tilt angle, guides and compresses the slider 3, thereby pushing the slider 3 to the center of the groove 2. The slide 2 is equipped with a slider 3, which can position the sleeve 4 and the clamping plate 5. The sleeve 4 is installed inside the slider 3, which can house one end of the connecting rod 402 and position the angle of the connecting rod 402 when it slides. The inner wall of the sleeve 4 is equipped with a spring 401 and the connecting rod 402. The spring 401 can support the connecting rod 402 and pull the connecting rod 402 to retract into the sleeve 4. The other end of the connecting rod 402 is equipped with a clamping plate 5, which can abut and clamp the Teflon wire in the transfer box 1.
[0025] Multiple slides 2 are arrayed inside the transfer box 1. The slides 2 on both sides of the inner wall of the transfer box 1 are angled. The support plate 201 has an arc-shaped structure at one end and an inclined angle at the other end. It is connected to the inner wall of the slide 2 by bolts. The inclined angle of the support plate 201, combined with its own toughness, can push the slider 3 to slide to the center position of the slide 2. The slider 3 is located in the slide 2 and is slidably connected to the inner wall of the slide 2. The sleeve 4 is embedded in the slider 3. The two ends of the spring 401 are connected to the inner wall of the sleeve 4 and the connecting rod 402 respectively. One end of the connecting rod 402 is located in the sleeve 4 and is slidably connected to the inner wall of the sleeve 4. The other end extends to the outside and is connected to the clamping plate 5.
[0026] In this embodiment: After the wire is placed in the transfer box 1, the clamp 5 inside the transfer box 1 can abut against the outside of the wire, thereby preventing the wire from directly contacting the inner wall of the transfer box 1, effectively reducing the friction between the Teflon wire and the transfer box 1 during the transfer process. The sleeve 4 and slider 3 outside the clamp 5 support and restrict the position of the Teflon wire, preventing large displacement of its position and improving the stability of the Teflon wire during the transfer process. At the same time, when the transfer box 1 shakes after the clamp 5 clamps the wire, the outside of the clamp 5 can drive the slider 3 to slide in the groove 2, thereby reducing the shaking and suppressing the transmission of shaking. It can also drive the Teflon wire to move with the clamp 5 in the transfer box 1. The structure of the wire is restricted by the clamp 5 at multiple points outside the Teflon wire, preventing the Teflon wire from bending or deforming when shaking.
[0027] Example 2: This example is an improvement on Example 1. For details, please refer to [link / reference]. Figures 2-5A mounting frame 6 is provided on the top of the clamping plate 5. A winding roller 7 is installed inside the mounting frame 6 of one side of the clamping plate 5 in the transfer box 1. The winding roller 7 can rotate within the mounting frame 6 by the torque of a spring shaft, thereby winding up the connecting rope 701. The connecting rope 701 is installed inside the winding roller 7. The other end of the connecting rope 701 is connected to a locking block 702, thus linking the connecting rope 701 with the winding roller 7. The other end of the connecting rope 701 is provided with a locking block 702. The structure of the locking block 702 corresponds angularly to the gear 8 inside the mounting frame 6 on the other side of the clamping plate 5. The mounting frame 6 of the other side of the clamping plate 5 in the transfer box 1... A gear 8 is installed inside the mounting frame 6. When the locking block 702 is inserted into the mounting frame 6, it can abut against the toothed block outside the gear 8. A connecting shaft 9 is installed inside the gear 8. The connecting shaft 9 is coaxially connected to the gear 8, thereby driving the gear 8 to rotate inside the mounting frame 6. A lead screw 901 is installed inside the connecting shaft 9. The lead screw 901 can extend and retract inside the connecting shaft 9 by rotation. When it extends into the connecting shaft 9, it can abut against the inner wall of the mounting frame 6, thereby locking the connecting shaft 9 and the gear 8. When it is reversed and pulled out, the connecting shaft 9 can rotate. The lead screw 901 has a damping feel when rotating and can stop at will.
[0028] The mounting frame 6 is integrally formed with the top of the clamping plate 5. The take-up roller 7 is located in the mounting frame 6 in one side of the clamping plate 5 inside the transfer box 1, and is rotatably connected to the inner wall of the mounting frame 6 through a spring shaft. One end of the connecting rope 701 is wound inside the take-up roller 7, and the other end is connected to the locking block 702. One end of the locking block 702 is embedded in the mounting frame 6 by pulling up the connecting rope 701 through the take-up roller 7. The gear 8 is located in the mounting frame 6 at the top of the clamping plate 5 on the other side of the transfer box 1, and the connecting shaft 9 passes through the gear 8 and is rotatably connected to the inner wall of the mounting frame 6. One end of the lead screw 901 is embedded in the connecting shaft 9 and is rotatably connected to the connecting shaft 9.
[0029] In this embodiment: after the Teflon wire is placed into the transfer box 1, the clamp 5 can be pulled close to the wire, and the connecting rod 402 extends in the sleeve 4 to compress the spring 401 inside the sleeve 4. Then, the locking block 702 on the outside of the mounting frame 6 above the clamp 5 on one side of the wire is pulled, and the connecting rope 701 is extended. Then, the locking block 702 is inserted into the mounting frame 6 at the top of the clamp 5 on the other side of the wire, and abuts and meshes with the gear 8 inside the mounting frame 6. Then, the screw 901 is rotated to extend outward to release the lock on the connecting shaft 9. Then, the handle at the top of the connecting shaft 9 is used to drive it to rotate in the mounting frame 6, and the gear 8 moves with the locking block 702 in the mounting frame 6, thereby tightening the clamps 5 on both sides to squeeze the wire and maintain the clamping force.
[0030] The contents not described in detail in this specification are existing technologies known to those skilled in the art.
[0031] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A material transfer device for the production of Teflon wires, comprising a transfer box (1), wherein the transfer box (1) is provided with a support component for positioning the Teflon wires during transfer, characterized in that: The support assembly includes multiple slide grooves (2) arranged on both sides of the inner wall of the transfer box (1). Each slide groove (2) has a support plate (201) arranged on its inner wall. A slider (3) is arranged inside the slide groove (2). A sleeve (4) is arranged inside the slider (3). A spring (401) and a connecting rod (402) are arranged on the inner wall of the sleeve (4). A clamping plate (5) is arranged at the other end of the connecting rod (402). The clamping plate (5) is provided with an installation frame (6) at the top. A winding roller (7) is provided inside the installation frame (6) of one side of the clamping plate (5) in the transfer box (1). A connecting rope (701) is provided inside the winding roller (7). A locking block (702) is provided at the other end of the connecting rope (701). A gear (8) is provided inside the installation frame (6) of the clamping plate (5) on the other side of the transfer box (1). A connecting shaft (9) is provided inside the gear (8). A lead screw (901) is provided inside the connecting shaft (9).
2. The material transfer device for producing Teflon wires according to claim 1, characterized in that: Multiple slides (2) are arrayed inside the transfer box (1). The slides (2) on both sides of the inner wall of the transfer box (1) are angled. The support plate (201) has an arc-shaped structure at one end and an inclined angle at the other end. It is connected to the inner wall of the slide (2) by bolts. The inclined angle of the support plate (201) combined with its own toughness can push the slider (3) to slide to the center position of the slide (2).
3. The material transfer device for producing Teflon wires according to claim 2, characterized in that: The slider (3) is located in the groove (2) and is slidably connected to the inner wall of the groove (2). The sleeve (4) is embedded in the slider (3). The two ends of the spring (401) are respectively connected to the inner wall of the sleeve (4) and the connecting rod (402). One end of the connecting rod (402) is located in the sleeve (4) and is slidably connected to the inner wall of the sleeve (4). The other end extends to the outside and is connected to the clamp (5).
4. The material transfer device for producing Teflon wires according to claim 1, characterized in that: The mounting frame (6) is integrally formed with the top of the clamping plate (5). The winding roller (7) is located in the mounting frame (6) in one side of the clamping plate (5) inside the transfer box (1), and is rotatably connected to the inner wall of the mounting frame (6) through a spring shaft.
5. A material transfer device for the production of Teflon wires according to claim 4, characterized in that: One end of the connecting rope (701) is wound inside the take-up roller (7), and the other end is connected to the locking block (702). One end of the locking block (702) is embedded into the mounting frame (6) by pulling up the connecting rope (701) through the take-up roller (7).
6. A material transfer device for the production of Teflon wires according to claim 4, characterized in that: The gear (8) is located in the mounting frame (6) on the top of the clamping plate (5) on the other side of the transfer box (1), and the connecting shaft (9) passes through the gear (8) and is rotatably connected to the inner wall of the mounting frame (6). One end of the lead screw (901) is embedded in the connecting shaft (9) and is rotatably connected to the connecting shaft (9).