A cable stripping machine for cable production
By designing a bidirectional moving component and a V-shaped conveyor roller structure, the problem of adapting traditional cable stripping machines to cables of different diameters has been solved, achieving automatic centering and stable conveying of cables, and improving stripping efficiency and cutting quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- YIXING ZHENGTUO METAL MATERIALS CO LTD
- Filing Date
- 2025-07-03
- Publication Date
- 2026-06-26
AI Technical Summary
Traditional cable stripping machines are difficult to adapt to cables of different diameters, require complicated adjustments, produce poor cutting quality, and lack automatic centering functions in the conveying mechanism, resulting in low stripping efficiency.
By employing a bidirectional moving component and a V-shaped conveyor roller structure, combined with a servo motor and a synchronous motor, the cutting blade can be synchronously adjusted and the spacing of the V-shaped conveyor rollers can be adjusted, ensuring automatic centering and stable cable delivery.
It improves the adaptability and stripping efficiency of cable strippers, ensures cut quality, and is suitable for efficient stripping of cables of various specifications.
Smart Images

Figure CN224418302U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of cable stripping technology, and in particular to a cable stripping machine for cable production. Background Technology
[0002] A cable stripper is a specialized piece of equipment used to strip the outer sheath of cables. Through precise cutting and stripping mechanisms, it can efficiently remove the cable insulation layer or sheath while protecting the internal conductor from damage.
[0003] Currently, cable stripping machines are needed during the production, processing, and recycling of cables.
[0004] Traditional cable stripping machines mostly use a fixed cutting structure, which is difficult to adapt to cables of different diameters, resulting in cumbersome adjustments, low efficiency, and a tendency to affect the cut quality due to misalignment. In addition, the conveying mechanism of existing equipment usually uses a single roller structure and lacks automatic centering function, which can easily lead to misalignment when conveying cables of different specifications, affecting the stripping quality.
[0005] Therefore, a cable stripping machine for cable production is proposed. Utility Model Content
[0006] This utility model is a cable stripping machine for cable production proposed to overcome the shortcomings of the existing technology.
[0007] To achieve the above objectives, the present invention adopts the following technical solution: a cable stripping machine for cable production, comprising a frame and a controller, a guide rail seat fixed at the top center of the frame, a bidirectional moving component mounted on the guide rail seat, a first bearing seat fixedly connected to each of the two movable ends of the bidirectional moving component, a connecting shaft fixedly connected to the inner ring of the bearings built into the two first bearing seats, and a cutting blade detachably fixed to the bottom of each of the two connecting shafts.
[0008] The guide rail seat has four second bearing seats on both sides. The eight second bearing seats are arranged in pairs. The inner rings of the bearings built into the two second bearing seats in the same group are fixedly connected to the V-shaped conveying roller.
[0009] A slider is fixedly connected to one side of the outer surface of each of the eight second bearing housings;
[0010] A first support frame is fixedly connected to one side of the top of the guide rail base. The first support frame is rotatably mounted with two adjusting screws, and the adjusting screws are connected to two adjacent sliders.
[0011] Both adjusting screws are equipped with a synchronous motor on one side, and the synchronous motor is fixedly connected to the seat of the adjacent second bearing seat, and the output shaft of the synchronous motor is fixedly connected to the adjacent V-shaped conveyor roller.
[0012] Furthermore, the bidirectional moving component includes a servo motor, which is fixedly mounted on one side of the outer surface of the guide rail seat. The drive end of the servo motor is fixedly connected to a first bidirectional screw, which passes through the guide rail seat and is rotatably connected to it. Two slides are symmetrically threaded on the outer surface of the first bidirectional screw, and the slides are slidably connected to the guide rail seat and fixedly connected to the seat body of the first bearing seat. This structure enables synchronous and accurate adjustment of the two cutting blades.
[0013] Furthermore, both connecting shafts are fixedly connected to the cutting blade using multiple bolts. This detachable connection method facilitates quick replacement and maintenance of the cutting blade.
[0014] Furthermore, both adjusting screws include handwheels, which are located on the top of the first support frame. A second bidirectional screw is fixedly connected to the bottom of the handwheel, and the second bidirectional screw passes through the first support frame and is rotatably connected to it. The second bidirectional screw is threadedly connected to two adjacent sliders. The handwheel adjustment method enables convenient adjustment of the V-shaped conveyor roller spacing, improving the equipment's adaptability to cables of different specifications.
[0015] Furthermore, a second support frame is fixedly connected to one side of the top of the frame, and two guide rods are fixedly connected between the frame and the second support frame. The guide rods are slidably connected to two adjacent sliders. The cooperation between the guide rods and the sliders ensures the smooth movement of the V-shaped conveyor roller during the adjustment process, thereby improving the stability of the equipment.
[0016] Furthermore, the controller is electrically connected to the servo motor and the synchronous motor, which facilitates the control of the overall operation.
[0017] The beneficial effects of this utility model are:
[0018] In use, this utility model is a cable stripping machine for cable production. The bidirectional moving component drives two cutting blades to move synchronously in opposite directions, which can quickly adapt to the stripping needs of cables with different diameters. With the spacing adjustment and synchronous drive function of the V-shaped conveying roller, the automatic centering and positioning of the cable and stable conveying are realized. The overall structure is compact and highly coordinated, which significantly improves the stripping efficiency and cutting quality. It is suitable for efficient stripping operations of cables of various specifications. Attached Figure Description
[0019] To more clearly illustrate the technical solution of this utility model, the drawings used in the description of the specific embodiments 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.
[0020] Figure 1 : A perspective view of this utility model;
[0021] Figure 2 The present utility model Figure 1 Enlarged view of point A in the middle;
[0022] Figure 3 : A cross-sectional view of the guide rail seat of this utility model.
[0023] The attached figures are labeled as follows:
[0024] 1. Frame; 2. Slide; 3. Second support frame; 4. Second bidirectional screw; 5. Controller; 6. Synchronous motor; 7. Guide rail seat; 8. Handwheel; 9. First support frame; 10. Second bearing seat; 11. Guide rod; 12. V-shaped conveyor roller; 13. Slider; 14. Servo motor; 15. First bidirectional screw; 16. Cutting blade; 17. Connecting shaft; 18. First bearing seat. Detailed Implementation
[0025] 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 skilled in the art without creative effort are within the protection scope of the present utility model.
[0026] like Figures 1 to 3 As shown, a cable stripping machine for cable production is disclosed, comprising a frame 1 and a controller 5. A guide rail 7 is fixed at the top center of the frame 1, and a bidirectional moving assembly is mounted on the guide rail 7. Both movable ends of the bidirectional moving assembly are fixedly connected to first bearing seats 18. The bidirectional moving assembly includes a servo motor 14, which is fixedly mounted on one side of the outer surface of the guide rail 7. A first bidirectional screw 15 is fixedly connected to the drive end of the servo motor 14, and the first bidirectional screw 15 passes through the guide rail 7 and is rotatably connected thereto. The thread helix angle is smaller than the friction angle, which gives the first bidirectional screw 15 a self-locking capability, preventing it from shifting due to vibration or load. The outer surface of the first bidirectional screw 15 is symmetrically threaded with two slides 2, and the slides 2 are slidably connected to the guide rail seat 7 and fixedly connected to the seat body of the first bearing seat 18. The inner rings of the bearings built into the two first bearing seats 18 are fixedly connected to the connecting shafts 17. The bottom of the two connecting shafts 17 can be detachably fixed with the cutting blade 16. The two connecting shafts 17 are fixedly connected to the cutting blade 16 by multiple bolts.
[0027] The guide rail seat 7 has four second bearing seats 10 on both sides. The eight second bearing seats 10 are in pairs. The inner rings of the bearings built into the two second bearing seats 10 in the same group are fixedly connected to the V-shaped conveyor roller 12.
[0028] Each of the eight second bearing seats 10 has a slider 13 fixedly connected to one side of its outer surface.
[0029] A first support frame 9 is fixedly connected to the top side of the guide rail seat 7. Two adjusting screws are rotatably mounted on the first support frame 9, and the adjusting screws are connected to two adjacent sliders 13. Both adjusting screws include a handwheel 8, and the handwheel 8 is located on the top of the first support frame 9. A second bidirectional screw 4 is fixedly connected to the bottom of the handwheel 8, and the second bidirectional screw 4 passes through the first support frame 9 and is rotatably connected to the first support frame 9. The second bidirectional screw 4 is threadedly connected to the two adjacent sliders 13. The thread helix angle of the second bidirectional screw 4 is smaller than the friction angle, so that the second bidirectional screw 4 has a self-locking ability and can prevent it from shifting on its own due to vibration or load.
[0030] Both adjusting screws are equipped with a synchronous motor 6 on one side, and the synchronous motor 6 is fixedly connected to the seat of the adjacent second bearing seat 10, and the output shaft of the synchronous motor 6 is fixedly connected to the adjacent V-shaped conveying roller 12.
[0031] A second support frame 3 is fixedly connected to one side of the top of the frame 1. Two guide rods 11 are fixedly connected between the frame 1 and the second support frame 3, and the guide rods 11 are slidably connected to two adjacent sliders 13.
[0032] The controller 5 is electrically connected to the servo motor 14 and the synchronous motor 6 to facilitate the control of the overall operation. The specific data analysis and processing involved to further realize the control function are methods that can be implemented by those skilled in the art based on common knowledge. These methods are not within the scope of this solution. The above description is only to illustrate the beneficial effects that can be achieved by this hardware structure improvement in conjunction with common knowledge.
[0033] Working principle: The handwheel 8 adjusts the second bidirectional screw 4, causing the sliders 13 on both sides to slide synchronously along the guide rod 11, so that the spacing of the V-shaped conveyor rollers 12 can adapt to different cable diameters and achieve automatic centering and positioning; the synchronous motor 6 drives the V-shaped conveyor rollers 12 to rotate, so as to achieve stable cable conveying. At the same time, the servo motor 14 drives the first bidirectional screw 15 to move the slide 2 and the cutting blade 16 in opposite directions, so that the spacing between the two cutting blades 16 matches the required cutting depth of the cable; during the cable conveying process, the cutting blades 16 squeeze and cut the cable sheath, completing the stripping operation.
[0034] The preferred embodiments of this utility model disclosed above are merely illustrative of the present utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the utility model to any specific implementation. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of this utility model, thereby enabling those skilled in the art to better understand and utilize it. This utility model is limited only by the claims and their full scope and equivalents.
Claims
1. A cable stripping machine for cable production, comprising a frame (1) and a controller (5), characterized in that: A guide rail seat (7) is fixed at the top center of the frame (1). A bidirectional moving component is installed on the guide rail seat (7). A first bearing seat (18) is fixedly connected to both movable ends of the bidirectional moving component. A connecting shaft (17) is fixedly connected to the inner ring of the bearing built into the two first bearing seats (18). A cutting blade (16) is detachably fixed to the bottom of the two connecting shafts (17). The guide rail seat (7) is provided with four second bearing seats (10) on both sides. The eight second bearing seats (10) are in pairs. The inner rings of the bearings built into the two second bearing seats (10) in the same group are fixedly connected to the V-shaped conveying roller (12). Each of the eight second bearing seats (10) has a slider (13) fixedly connected to one side of its outer surface; The top side of the guide rail seat (7) is fixedly connected to a first support frame (9), and the first support frame (9) is rotatably mounted with two adjusting screws, and the adjusting screws are connected to two adjacent sliders (13); Both of the adjusting screws are equipped with a synchronous motor (6) on one side, and the synchronous motor (6) is fixedly connected to the seat of the adjacent second bearing seat (10), and the output shaft of the synchronous motor (6) is fixedly connected to the adjacent V-shaped conveying roller (12).
2. The cable stripping machine for cable production according to claim 1, characterized in that: The bidirectional moving component includes a servo motor (14), which is fixedly installed on one side of the outer surface of the guide rail seat (7). The drive end of the servo motor (14) is fixedly connected to a first bidirectional screw (15), which passes through the guide rail seat (7) and is rotatably connected to it. The outer surface of the first bidirectional screw (15) is symmetrically threaded with two slides (2), which are slidably connected to the guide rail seat (7) and fixedly connected to the seat body of the first bearing seat (18).
3. The cable stripping machine for cable production according to claim 1, characterized in that: Both connecting shafts (17) are fixedly connected to the cutting blade (16) using multiple bolts.
4. The cable stripping machine for cable production according to claim 1, characterized in that: Both of the adjusting screws include a handwheel (8), and the handwheel (8) is located on the top of the first support frame (9). The bottom of the handwheel (8) is fixedly connected to a second bidirectional screw (4), and the second bidirectional screw (4) passes through the first support frame (9) and is rotatably connected to the first support frame (9). The second bidirectional screw (4) is threadedly connected to two adjacent sliders (13).
5. A cable stripping machine for cable production according to claim 4, characterized in that: A second support frame (3) is fixedly connected to one side of the top of the frame (1). Two guide rods (11) are fixedly connected between the frame (1) and the second support frame (3), and the guide rods (11) are slidably connected to two adjacent sliders (13).
6. A cable stripping machine for cable production according to claim 1, characterized in that: The controller (5) is electrically connected to the servo motor (14) and the synchronous motor (6).