Weaving equipment for rope and cord textile processing
By mechanizing the thread feed, the problem of low precision in manual adjustment is solved, enabling high-precision and stable weaving of rope and ribbon textiles, and improving the efficiency and quality of rope and ribbon textile processing.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- FOSHAN SHENGDU GARMENT ACCESSORIES CO LTD
- Filing Date
- 2025-07-01
- Publication Date
- 2026-06-30
AI Technical Summary
In existing rope and belt weaving equipment, the low precision of manual adjustment during the interlacing and winding of the silk threads leads to low weaving accuracy and poor stability, affecting the quality of the rope and belt and production efficiency.
A stepper motor drives the feed rack to feed along the slide box, which, together with the rotation of the transmission disc and yarn tube, achieves uniform feeding and stable winding of the yarn. The mechanized control of the braiding sleeve assembly and the feed assembly replaces manual operation.
It improves the stability and processing precision of rope weaving, reduces the difficulty of manual adjustment, and enhances production efficiency and product quality.
Smart Images

Figure CN224430906U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of rope and ribbon textile processing technology, and in particular to a weaving device for rope and ribbon textile processing. Background Technology
[0002] In the field of rope and ribbon textile processing, the performance of weaving equipment plays a decisive role in product quality. With the continuous development of the textile industry, higher requirements are put forward for the weaving precision and production efficiency of ropes and ribbons. From a technical perspective, traditional weaving equipment has gradually revealed many limitations when facing complex and diverse weaving needs, making it difficult to meet the development trend of modern textile industry towards refinement and high efficiency.
[0003] In existing rope and ribbon textile processing weaving devices, most rely on manual adjustment of the yarn pulling during the interlacing and winding process. However, manual operation is limited by human reaction speed and judgment accuracy, making it difficult to precisely control the yarn feed. If the yarn feed is unstable during weaving, it will lead to a decrease in the weaving precision of the ribbon, resulting in problems such as uneven weave patterns and inconsistent density. At the same time, during manual adjustment, the yarn is easily affected by external factors, such as slight hand tremors of the operator, which can cause instantaneous changes in the force on the yarn, resulting in poor yarn pulling stability and seriously affecting the weaving quality of the rope and ribbon. This series of problems caused by low precision of manual adjustment greatly limits the efficiency of rope and ribbon textile processing and the improvement of product quality. Utility Model Content
[0004] In order to overcome the problems of low weaving accuracy and poor stability of the woven belt due to the low precision of manual adjustment of the pulling and feeding of the silk threads during the weaving process of existing rope and belt textile processing, this utility model provides a weaving device for rope and belt textile processing.
[0005] The technical solution is as follows: A braiding device for rope and belt textile processing includes a braiding assembly, a feeding assembly, and a braiding sleeve assembly; the braiding assembly has a braiding sleeve assembly inside; a feeding assembly is provided at one end of the braiding sleeve assembly; the braiding assembly includes a support, a transmission disc, a turntable, and a yarn tube; the feeding assembly includes a chute, a feeding rack, and a stepper motor; the braiding sleeve assembly includes a winding tube and a connecting rod; a winding tube is provided inside the center of the support, and the winding tube passes through the support.
[0006] Furthermore, a connecting rod is provided at one end of the spiral wound tube, and the connecting rod is fixedly connected to the spiral wound tube with bolts.
[0007] Furthermore, a feed rack is provided at the lower end of the connecting rod, and the feed rack is fixedly connected to the connecting rod.
[0008] Furthermore, a grooved chamber is provided on the outside of the feed rack, and the feed rack is slidably connected along the inner wall of the grooved chamber.
[0009] Furthermore, a stepper motor is provided in front of the feed rack, and the output end of the stepper motor is connected to the lower end of the feed rack via gear transmission.
[0010] Furthermore, a transmission disc is provided around the outer circumference of the winding tube; a turntable is provided on the other side of the bracket, and the turntable is connected to the transmission disc via a rod; a drive motor is provided at the front of the winding tube, and the output end of the drive motor is connected to the transmission disc via a synchronous belt drive.
[0011] Furthermore, yarn tubes are provided on the outer side of the turntable, and the yarn tubes are rotatably connected to the turntable; two yarn tubes on the same turntable are symmetrically arranged about the axis of the turntable.
[0012] The beneficial effects are: This utility model drives the transmission disk to rotate by a drive motor, which in turn drives the turntable and yarn tube to rotate. At this time, the yarns drawn out from the two adjacent yarn tubes are fixed on the winding tube. At the same time, the stepper motor drives the feed rack to feed forward along the inside of the slide groove, thereby causing the feed rack, connecting rod and winding tube to feed and move. The moving winding tube, in conjunction with the rotating yarn tube, causes the winding tube to continuously wind the yarn, thereby realizing the alternating weaving of the yarn.
[0013] By using a stepper motor, a feed rack, and a chute, the stepper motor drives the feed rack to feed forward along the inside of the chute, allowing the winding tube to move at a constant speed. This improves the stability of the rope weaving, reduces the difficulty of manual weaving feed adjustment, and increases processing accuracy. Attached Figure Description
[0014] Figure 1 This is a schematic diagram of the overall three-dimensional structure of this utility model;
[0015] Figure 2 This is a schematic diagram of the overall rear-view three-dimensional structure of this utility model;
[0016] Figure 3 This is a schematic diagram of the overall internal three-dimensional structure of this utility model;
[0017] Figure 4 This is a three-dimensional structural diagram of the combined transmission disc, turntable, and yarn tube of this utility model;
[0018] Figure 5 This is a three-dimensional structural diagram of the combination of the winding tube, connecting rod, and feed rack of this utility model.
[0019] In the attached drawings, the following are the reference numerals: 1. Braiding assembly; 2. Feeding assembly; 3. Braiding sleeve assembly; 101. Support; 102. Transmission disc; 103. Turntable; 104. Yarn tube; 105. Drive motor; 201. Slide chamber; 202. Feed rack; 203. Stepper motor; 301. Winding tube; 302. Connecting rod. Detailed Implementation
[0020] The present invention will now be described in detail with reference to the accompanying drawings and specific embodiments.
[0021] Example 1
[0022] like Figures 1-5 As shown, the braiding device for rope and ribbon textile processing includes a braiding assembly 1, a feeding assembly 2, and a braiding sleeve assembly 3. The braiding sleeve assembly 3 is disposed inside the braiding assembly 1. The feeding assembly 2 is disposed at one end of the braiding sleeve assembly 3. The braiding assembly 1 includes a bracket 101, a transmission disc 102, a turntable 103, and a yarn tube 104. The feeding assembly 2 includes a chute 201, a feeding rack 202, and a stepper motor 203. The braiding sleeve assembly 3 includes a winding tube 301 and a connecting rod 302. The winding tube 301 is disposed inside the center of the bracket 101 and passes through the bracket 101.
[0023] One end of the spiral wound tube 301 is provided with a connecting rod 302, and the connecting rod 302 is bolted to the spiral wound tube 301.
[0024] The lower end of the connecting rod 302 is provided with a feed rack 202, and the feed rack 202 is fixedly connected to the connecting rod 302.
[0025] The feed rack 202 is provided with a grooved chamber 201 on its outside, and the feed rack 202 is slidably connected along the inner wall of the grooved chamber 201.
[0026] A stepper motor 203 is provided in front of the feed rack 202, and the output end of the stepper motor 203 is connected to the lower end of the feed rack 202 via gear transmission.
[0027] When the drive motor 105 is powered on, its internal rotor rotates at high speed, transmitting power to the transmission disc 102 via a synchronous belt drive structure. The transmission disc 102, receiving power, begins to rotate and, through its mechanical connection with the turntable 103, drives the turntable 103 to rotate synchronously. The yarn tubes 104, mounted on the turntable 103, rotate along with it. The threads extending from adjacent yarn tubes 104 are manually fixed to the winding tube 301, laying the foundation for weaving the threads into a rope. Simultaneously, the stepper motor 203 receives a control signal and starts. The output shaft of the stepper motor 203... The gear connected to it rotates, and the gear meshes with the feed rack 202. As the gear rotates, the feed rack 202 is pushed forward along the internal track of the slide chamber 201. The feed rack 202 is connected to the winding tube 301 through the connecting rod 302. When the feed rack 202 moves, it pulls the connecting rod 302, which in turn drives the winding tube 301 to move forward synchronously. With the yarn tube 104 continuously rotating and feeding out the yarn, and the winding tube 301 continuously moving forward, the yarn is wound around the winding tube 301 in an orderly manner, gradually forming a rope, thereby realizing the alternating weaving of the yarn.
[0028] Example 2
[0029] Based on Example 1, such as Figures 1-5 As shown, a transmission disc 102 is provided around the outer perimeter of the winding tube 301; a turntable 103 is provided on the other side of the bracket 101, and the turntable 103 is connected to the transmission disc 102 by a rod; a drive motor 105 is provided in front of the winding tube 301, and the output end of the drive motor 105 is connected to the transmission disc 102 by a synchronous belt drive.
[0030] A yarn tube 104 is provided on the outer side of the turntable 103, and the yarn tube 104 is rotatably connected to the turntable 103; two yarn tubes 104 on the same turntable 103 are symmetrically arranged about the axis of the turntable 103.
[0031] With the stepper motor 203, feed rack 202, and slide box 201, the stepper motor 203 drives the feed rack 202 to feed forward along the inside of the slide box 201, so that the winding tube 301 feeds and moves at a constant speed, thereby improving the stability of rope weaving, reducing the difficulty of manual weaving feed adjustment, and improving processing accuracy.
Claims
1. A braiding device for the textile processing of a rope, comprising a braiding assembly (1), characterized in that: It also includes a feeding assembly (2) and a braided sleeve assembly (3); the braided sleeve assembly (3) is provided inside the braided assembly (1); the feeding assembly (2) is provided at one end of the braided sleeve assembly (3); the braided assembly (1) includes a bracket (101), a transmission disc (102), a turntable (103), and a yarn tube (104); the feeding assembly (2) includes a chute (201), a feeding rack (202), and a stepper motor (203); the braided sleeve assembly (3) includes a winding tube (301) and a connecting rod (302); the winding tube (301) is provided inside the center of the bracket (101), and the winding tube (301) passes through the bracket (101).
2. The braiding apparatus for rope textile processing according to claim 1, characterized in that: A connecting rod (302) is provided at one end of the spiral tube (301), and the connecting rod (302) is bolted to the spiral tube (301).
3. The braiding apparatus for rope and belt textile processing according to claim 2, characterized in that: The lower end of the connecting rod (302) is provided with a feed rack (202), and the feed rack (202) is fixedly connected to the connecting rod (302).
4. The braiding apparatus for rope and belt textile processing according to claim 3, characterized in that: The feed rack (202) is provided with a grooved chamber (201) on its outside, and the feed rack (202) is slidably connected along the inner wall of the grooved chamber (201).
5. The braiding apparatus for rope and belt textile processing according to claim 3, wherein: A stepper motor (203) is provided in front of the feed rack (202), and the output end of the stepper motor (203) is connected to the lower end of the feed rack (202) via gear transmission.
6. The braiding apparatus for cord textile processing of claim 1, wherein: A drive disc (102) is provided around the outer perimeter of the winding tube (301); a turntable (103) is provided on the other side of the bracket (101), and the turntable (103) is connected to the drive disc (102) by a rod; a drive motor (105) is provided in front of the winding tube (301), and the output end of the drive motor (105) is connected to the drive disc (102) by a synchronous belt drive.
7. The braiding apparatus of claim 6, wherein: A yarn tube (104) is provided on the outside of the turntable (103), and the yarn tube (104) is rotatably connected to the turntable (103); the two yarn tubes (104) on the same turntable (103) are symmetrically arranged about the axis of the turntable (103).