A device for processing the frayed edges of clothing

By setting calibration mechanisms and sensors at the feed and discharge ends of the feeding table, and combining them with electric slide rails and sliders to adjust the fabric position, the problem of inconsistent fabric feeding speed and overlocking speed was solved, thus improving the stability and production efficiency of frayed edge processing.

CN224430913UActive Publication Date: 2026-06-30HANGZHOU FEIHONG KNITTING FINERY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HANGZHOU FEIHONG KNITTING FINERY CO LTD
Filing Date
2025-05-15
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Existing frayed edge processing devices suffer from inconsistent fabric feed speed and overlock speed, resulting in unstable processing effects. Furthermore, the lack of integrated equipment increases operational complexity and reduces production efficiency.

Method used

A calibration mechanism is set at the inlet and outlet of the feeding platform. Combined with the sensor on the pressure frame, the position of the fabric is monitored in real time. The movement of the fabric is controlled by the electric slide rail and slider adjustment to ensure consistency. At the end of processing, the tail material is output by the screw driven by the drive motor to achieve smooth conveying.

Benefits of technology

It achieves stable consistency in the processing of rough edges and overlocking, improves production efficiency and overall equipment stability, and reduces the instability caused by manual intervention.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224430913U_ABST
    Figure CN224430913U_ABST
Patent Text Reader

Abstract

This utility model discloses a garment frayed edge processing device, including a base and a frayed edge sewing machine and a frayed edge machine mounted on top of it. The processing areas of the frayed edge sewing machine and the frayed edge machine are jointly provided with a feeding platform for garment processing. The feeding platform has a calibration mechanism at both the inlet and outlet ends, a pressing mechanism at the top of the feeding platform, and a third and fourth conveyor in the middle of the feeding platform for conveying the corrected garment. This utility model, by setting calibration mechanisms at both the inlet and outlet ends of the feeding platform, and using sensors on one side of the pressing frame to monitor the movement of the garment during processing in real time to detect any positional deviations, allows the electric slide rail and electric slider inside the calibration mechanism to drive the second and first conveyors to control the horizontal movement of the garment, returning the deviated garment to its original position. This ensures consistency between the frayed edge processing and the subsequent overlocking operation, improving production efficiency.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of garment processing technology, specifically to a device for processing the frayed edges of clothing. Background Technology

[0002] In the garment manufacturing industry, frayed edges, as a unique decorative technique, are widely used in various clothing styles, such as jeans and Chanel-style jackets, adding a sense of fashion and artistry. Frayed edge processing equipment is mainly used to treat the edges of garments, creating regular or irregular frayed effects to meet different design requirements. However, existing frayed edge processing equipment still has many problems in practical use and urgently needs improvement.

[0003] Existing frayed edge processing devices on the market have significant drawbacks in processing garment frayed edges. To prevent seam slippage, workers typically need to manually hold the fabric and simultaneously advance it outside the machine. However, it is difficult to precisely control the fabric's advance speed to match the seam-sealing speed using manual pushing, resulting in inconsistent processing quality and difficulty in achieving uniform frayed edge length and shape. Furthermore, the market currently lacks equipment that integrates frayed edge processing with post-processing seam-sealing, requiring the entire process to be completed in steps. This not only increases operational complexity but also significantly limits production efficiency.

[0004] Therefore, a device for processing the frayed edges of clothing is proposed. Utility Model Content

[0005] The purpose of this invention is to provide a device for processing the frayed edges of clothing, so as to solve the problems mentioned in the background art.

[0006] To achieve the above objectives, this utility model provides the following technical solution: a garment frayed edge processing device, comprising a base and a frayed edge sewing machine and a frayed edge machine disposed on its top, wherein the processing areas of the frayed edge sewing machine and the frayed edge machine are jointly provided with a feeding platform for garment processing, wherein the feeding end and the discharging end of the feeding platform are both provided with calibration mechanisms, the top of the feeding platform is provided with a pressing mechanism, and the middle of the feeding platform is provided with a third conveyor and a fourth conveyor for conveying the corrected garment material;

[0007] The calibration mechanism includes a second feeder and a first feeder. An electric slider is connected to one side of both the second feeder and the first feeder. An electric slide rail is slidably connected to the outer side wall of the electric slider and is fixedly connected to the base.

[0008] The pressing mechanism includes a pressing frame. One side of the pressing frame is connected to a sensor for real-time monitoring of the fabric's movement position and offset. Another side of the pressing frame is connected to a lifting mechanism. Based on the real-time monitoring data from the sensor, the electric slide rail and electric slider are controlled in real-time to drive the second and first feeders to control the horizontal movement of the fabric, adjust its position, and ensure the consistency of the fabric processing.

[0009] Preferably, the lifting mechanism includes a fixed frame fixedly installed on the top of the base, the pressure frame slidably installed inside the fixed frame, a connecting plate installed on one side of the pressure frame, and buffer springs installed opposite each other on the top of the connecting plate, with the upper ends of the two buffer springs both installed on the fixed frame.

[0010] Preferably, the lifting mechanism further includes an electric cylinder fixedly installed on the top of the connecting plate, one side of the electric cylinder being fixedly connected to the fixed frame, and a protective pad being connected to the side of the pressing frame near the fabric contact surface.

[0011] Preferably, a movable platform is installed on the top of the electric slider, and mounting seats are installed on one side of the movable platform, the third conveyor, and the fourth conveyor. Lifting seats are slidably installed inside the multiple mounting seats, and fixing bolts are threaded inside the multiple lifting seats. The lower ends of the multiple fixing bolts are rotatably installed on the corresponding mounting seats. Rotating the corresponding fixing bolts can control the up and down movement of the corresponding third conveyor, fourth conveyor, and second conveyor, and adjust the conveying pressure.

[0012] Preferably, a screw is installed on the common internal thread of the two mounting seats in the middle, and one end of the screw is connected to a drive motor.

[0013] Preferably, a guide rail is slidably mounted on one side of both mounting bases, the guide rail is fixedly mounted on the top of the base, and fixing blocks are rotatably mounted on both ends of the screw, with both fixing blocks fixedly mounted on the top of the base.

[0014] Preferably, both ends of the two calibration mechanisms are provided with guide platforms, both guide platforms are fixedly installed on the base, and the input ends of the third and fourth feeders are connected with connecting wheels, and the two connecting wheels are connected to each other through a transmission chain.

[0015] Compared with the prior art, the beneficial effects of this utility model are:

[0016] 1. This utility model sets up calibration mechanisms at both the infeed and discharge ends of the feeding table. In conjunction with sensors on one side of the pressing frame, it monitors in real time whether the position of the fabric deviates during processing. Once a deviation occurs, the electric slide rail and electric slider inside the calibration mechanism drive the second and first feeders to control the horizontal movement of the fabric, so that the deviated fabric returns to its original position. This ensures the consistency of the fabric during the processing of the frayed edges and the subsequent overlocking operation. By setting up integrated processing, it not only replaces the instability of traditional manual feeding, but also improves production efficiency.

[0017] 2. When the fabric is processed by the sewing machine and the edge sewing machine to the end, the third or fourth feeder is controlled to stop the material conveying. At this time, the material is still pressed. The drive motor is controlled to drive the screw to rotate, thereby driving the tail material to cooperate with the calibration mechanism at the output end to discharge the material. The fabric is smoothly conveyed until all the material is processed, thereby improving the overall processing stability of the equipment. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the main structure of this utility model;

[0019] Figure 2 This is a cross-sectional structural diagram of the present invention;

[0020] Figure 3 This is a schematic diagram of the calibration mechanism of this utility model.

[0021] In the diagram: 1. Base; 2. Edge sewing machine; 3. Edge sewing machine; 4. Feeding table; 5. Calibration mechanism; 51. Electric slide rail; 52. Electric slider; 53. Moving table; 54. Mounting base; 55. Second feeder; 56. First feeder; 57. Lifting seat; 58. Fixing bolt; 6. Third feeder; 7. Fourth feeder; 8. Connecting wheel; 9. Transmission chain; 11. Screw; 12. Fixing block; 13. Drive motor; 14. Fixing frame; 15. Pressing frame; 16. Connecting plate; 17. Buffer spring; 18. Electric cylinder. 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] Example 1: Please refer to Figure 1-3This utility model provides a technical solution: a garment frayed edge processing device, including a base 1 and frayed edge sewing machine 2 and frayed edge machine 3 set on its top. The processing areas of the frayed edge sewing machine 2 and frayed edge machine 3 are jointly provided with a feeding table 4 for garment processing. The feeding table 4 is provided with a calibration mechanism 5 at both the feeding end and the discharging end. The top of the feeding table 4 is provided with a pressing mechanism. The middle of the feeding table 4 is provided with a third conveyor 6 and a fourth conveyor 7 for conveying the corrected garment. The pressing mechanism ensures that the fabric is pressed down during the processing to prevent deviation during processing.

[0024] The calibration mechanism 5 includes a second feeder 55 and a first feeder 56. The second feeder 55 and the first feeder 56 are connected to an electric slider 52 on one side. The outer side wall of the electric slider 52 is slidably connected to an electric slide rail 51 and fixedly connected to the base 1. It should be noted that the feeder is the same as the conveyor, which is the prior art and will not be explained in detail here.

[0025] The pressing mechanism includes a pressing frame 15. A sensor for real-time monitoring of the fabric's movement position and offset is connected to one side of the pressing frame 15. A lifting mechanism is also connected to one side of the pressing frame 15. Based on the real-time monitoring data from the sensor, the electric slide rail 51 and electric slider 52 are controlled in real time to drive the second feeder 55 and the first feeder 56 to control the horizontal movement of the fabric, adjust its position, and ensure the consistency of the fabric processing.

[0026] In this embodiment, the lifting mechanism includes a fixed frame 14 fixedly installed on the top of the base 1, a pressing frame 15 slidably installed inside the fixed frame 14, a connecting plate 16 installed on one side of the pressing frame 15, and buffer springs 17 installed opposite each other on the top of the connecting plate 16. The upper ends of the two buffer springs 17 are both installed on the fixed frame 14. The lifting mechanism also includes an electric cylinder 18 fixedly installed on the top of the connecting plate 16. One side of the electric cylinder 18 is fixedly connected to the fixed frame 14. A protective pad is connected to the side of the pressing frame 15 near the fabric contact surface. The protective pad improves the protective effect of the fabric.

[0027] In this embodiment, a movable platform 53 is installed on the top of the electric slider 52. Mounting bases 54 are installed on one side of the movable platform 53, the third conveyor 6, and the fourth conveyor 7. Lifting seats 57 are slidably installed inside the multiple mounting bases 54. Fixing bolts 58 are threadedly installed inside the multiple lifting seats 57. The lower ends of the multiple fixing bolts 58 are rotatably installed on the corresponding mounting bases 54. By rotating the corresponding fixing bolts 58, the corresponding third conveyor 6, fourth conveyor 7, and second conveyor 55 can be controlled to move up and down, and the conveying pressure can be adjusted. At the same time, it can also be set according to the thickness of the fabric to be produced, thereby improving the versatility of the equipment.

[0028] In this embodiment, when the fabric is processed to the end by the sewing machine 2 and the sewing machine 3, a screw 11 is installed on the common thread inside the two mounting seats 54 in the middle. One end of the screw 11 is connected to a drive motor 13. A guide rail is slidably installed on one side of the two mounting seats 54. The guide rail is fixedly installed on the top of the base 1. Fixing blocks 12 are rotatably installed on both ends of the screw 11. Both fixing blocks 12 are fixedly installed on the top of the base 1. By controlling the third feeder 6 or the fourth feeder 7 to stop the material conveying, the material is still pressed. By controlling the drive motor 13 to drive the screw 11 to rotate, the tail material is driven to cooperate with the calibration mechanism 5 at the output end to discharge the material, and the fabric is smoothly conveyed until all the material is processed, thereby improving the overall processing stability of the equipment.

[0029] In this embodiment, both ends of the two calibration mechanisms 5 are provided with guide platforms, and both guide platforms are fixedly installed on the base 1. The input ends of the third feeder 6 and the fourth feeder 7 are connected with connecting wheels 8, and the two connecting wheels 8 are rotatably connected through the transmission chain 9.

[0030] The working principle is as follows: In actual processing, the base 1 is first placed on a stable workbench. The sewing machine 2 and sewing machine 3 are then installed on top of the base 1, ensuring their stability. The feeding platform 4 is installed, and calibration mechanisms 5 are installed at the inlet and outlet ends of the feeding platform 4. During use, the height of the third feeder 6, the fourth feeder 7, and the second feeder 55 are adjusted by rotating the fixing bolt 58 according to the thickness of the fabric to be processed, to accommodate fabrics of different thicknesses. The feeding pressure is also adjusted. The monitoring parameters for fabric deviation are set by the sensor on one side of the pressure frame 15. The fabric is placed on the guide platform at the feeding end, allowing it to smoothly enter the calibration mechanism 5. The second feeder 55 and the first feeder 56 drive the fabric to the edge sewing machine 2 and the edge sewing machine 3. At the same time, the edge sewing machine 2 and the edge sewing machine 3 are started, and the fabric moves on the feeding platform 4. The pressure frame 15 presses down on the fabric under the action of the buffer spring 17 and the electric cylinder 18 to prevent the fabric from shifting. The sensor monitors the position of the fabric in real time. If the fabric shifts, the electric slide rail 51 and the electric slider 52 drive the second feeder 55 and the first feeder 56 to adjust the position of the fabric to ensure consistent processing.

[0031] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A garment frayed edge processing device, comprising a base (1) and a frayed edge sewing machine (2) and a frayed edge machine (3) disposed on top thereon, wherein the processing areas of the frayed edge sewing machine (2) and the frayed edge machine (3) are jointly provided with a feeding table (4) for garment processing, characterized in that: The feeding end and the discharge end of the feeding platform (4) are equipped with calibration mechanisms (5), the top of the feeding platform (4) is equipped with a pressing mechanism, and the middle of the feeding platform (4) is equipped with a third conveyor (6) and a fourth conveyor (7) for conveying the corrected fabric. The calibration mechanism (5) includes a second feeder (55) and a first feeder (56). An electric slider (52) is connected to one side of the second feeder (55) and the first feeder (56). An electric slide rail (51) is slidably connected to the outer wall of the electric slider (52) and fixedly connected to the base (1). The pressing mechanism includes a pressing frame (15). A sensor for real-time monitoring of the fabric's movement position and offset is connected to one side of the pressing frame (15). A lifting mechanism is connected to one side of the pressing frame (15). Based on the real-time monitoring data from the sensor, the electric slide rail (51) and electric slider (52) are controlled in real time to drive the second feeder (55) and the first feeder (56) to control the horizontal movement of the fabric, adjust its position, and ensure the consistency of the fabric processing.

2. The garment fringing processing device according to claim 1, characterized in that: The lifting mechanism includes a fixed frame (14) fixedly installed on the top of the base (1), a pressure frame (15) slidably installed inside the fixed frame (14), a connecting plate (16) installed on one side of the pressure frame (15), and a buffer spring (17) installed opposite to the top of the connecting plate (16). The upper ends of the two buffer springs (17) are both installed on the fixed frame (14).

3. The garment fringing processing device according to claim 2, characterized in that: The lifting mechanism also includes an electric cylinder (18) fixedly installed on the top of the connecting plate (16). One side of the electric cylinder (18) is fixedly connected to the fixed frame (14), and a protective pad is connected to the side of the pressing frame (15) near the fabric contact surface.

4. The garment fringing processing device according to claim 1, characterized in that: The top of the electric slider (52) is equipped with a moving platform (53). The moving platform (53), the third conveyor (6), and the fourth conveyor (7) are all equipped with mounting seats (54) on one side. Lifting seats (57) are slidably installed inside the multiple mounting seats (54). Fixing bolts (58) are threaded inside the multiple lifting seats (57). The lower ends of the multiple fixing bolts (58) are rotatably installed on the corresponding mounting seats (54). Rotating the corresponding fixing bolts (58) can control the corresponding third conveyor (6), fourth conveyor (7), and second conveyor (55) to move up and down, and adjust the conveying pressure.

5. The garment fringing processing device according to claim 1, characterized in that: The two mounting bases (54) in the middle are connected to a common thread for a screw (11), and one end of the screw (11) is connected to a drive motor (13).

6. The garment fringing processing device according to claim 5, characterized in that: The two mounting bases (54) are slidably mounted on one side of each other, and the guide rails are fixedly mounted on the top of the base (1). Both ends of the screw (11) are rotatably mounted with fixing blocks (12), and both fixing blocks (12) are fixedly mounted on the top of the base (1).

7. A garment frayed edge processing device according to any one of claims 1-6, characterized in that: Both ends of the two calibration mechanisms (5) are provided with guide platforms, and both guide platforms are fixedly installed on the base (1). The input ends of the third feeder (6) and the fourth feeder (7) are connected with connecting wheels (8), and the two connecting wheels (8) are connected to each other through a transmission chain (9).