A host device for detecting webbing quality

By designing an automatic flipping and cleaning main unit, the problems of low efficiency and environmental pollution in traditional webbing quality inspection have been solved, achieving an efficient and stable webbing inspection and cleaning process.

CN224467157UActive Publication Date: 2026-07-07SHENZHEN SIHAISHENGDIAN TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN SIHAISHENGDIAN TECH CO LTD
Filing Date
2025-07-10
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Traditional webbing quality inspection relies on manual operation, which is inefficient. Furthermore, manual cleaning is required when dust or cotton lint is found, which poses risks of inefficiency and environmental pollution.

Method used

Design a main unit that utilizes multiple sets of rollers and gear belt structure to achieve automatic turning and cleaning of woven belts, automatically removes debris through drive motor and debris removal components, integrates a collection system, and improves detection efficiency and stability.

Benefits of technology

It enables automatic flipping and cleaning of woven belts, improves inspection efficiency, avoids the inefficiency and environmental pollution of manual operation, and ensures production stability and cleaning effect.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to the technical field of fabric production, and disclose a host computer equipment for detecting the quality of braid, including support, installation panel, discharging spare, material receiving spare and impurity removing spare, is fixed with installation panel on the support, is equipped with a plurality of roll bodies for the auxiliary material surface of installation panel is equipped with, concretely is installation panel top two ends respectively set up and send material roll no.
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Description

Technical Field

[0001] This utility model relates to the field of fabric production technology, specifically to a main equipment for detecting the quality of webbing. Background Technology

[0002] Webbing is a narrow-width fabric, typically made of yarn, polyester, nylon, or cotton, produced through weaving, knitting, or machine weaving processes. It has a ribbon-like shape, and in the textile industry, quality inspection of webbing is a crucial step in ensuring product consistency. Traditional inspection processes rely heavily on manual operation, requiring repeated flipping and segment-by-segment inspection of the webbing, resulting in low efficiency. Furthermore, when loose dust or cotton lint is detected on the webbing, tools are needed for cleaning, which introduces certain drawbacks. Utility Model Content

[0003] To address the shortcomings of existing technologies, this utility model provides a main equipment for detecting the quality of webbing. It has the advantages of improving the efficiency of turning the webbing over and cleaning it. This solves the problem that the current method mainly relies on manual labor to repeatedly turn the webbing over for inspection, and requires manual cleaning with tools after dust and debris are found, which is inefficient.

[0004] To achieve the above objectives, this utility model provides the following technical solution: A main equipment for detecting the quality of webbing includes a bracket, a mounting panel, a feeding component, a receiving component, and a cleaning component. The mounting panel is fixed on the bracket, and multiple rollers for assisting in turning the material over are provided on the surface of the mounting panel. Specifically, a feeding roller 1 and a feeding roller 2 are respectively provided at both ends of the top of the mounting panel, and a turning roller and a guide roller are respectively provided at both ends of the bottom of the mounting panel. The mounting panel is fixed vertically on the bracket, so that the mounting panel is perpendicular to the upper surface of the bracket. The feeding roller 1 and the feeding roller 2 are used to output the webbing, the turning roller is used to turn the output webbing over, and the guide roller is used to guide the webbing to be wound up.

[0005] The surface of the mounting panel is equipped with an auxiliary roller and a stabilizing component located between the second feeding roller and the turning roller. The bottom of the braided belt is attached to the side of the second feeding roller and the front end of the braided belt is guided to pass from the bottom of one side of the turning roller to the other side. At this time, the top of the braided belt is attached to the side of the auxiliary roller, so that the braided belt can achieve the turning effect by passing through the turning roller.

[0006] The surface of the mounting panel is equipped with a support rod located between the feed roller and the guide roller. During output and retraction, the braided belt adheres to the side of the support rod, improving the stability of the braided belt conveyor.

[0007] The mounting panel has a feeding component and a receiving component positioned opposite each other on one end. The feeding component is movably connected to a woven belt, which is attached to multiple rollers and stabilizers. The front end of the woven belt is movably connected to the receiving component. The feeding component is used to output the woven belt outwards, and the receiving component is used to recycle the output and flipped woven belt.

[0008] The surface of the mounting panel is also equipped with a cleaning component for cleaning dust and debris from the side of the braided belt. The cleaning component is located between the feed roller and the support rod. When the braided belt is output, it is guided by the feed roller and passes through the cleaning component before sticking to the bottom of the support rod. Thus, the entire cleaning operation of the braided belt is completed while the braided belt is continuously output.

[0009] When in use, the main equipment for detecting the quality of webbing works by pulling the front end of the webbing wound on the side of the unwinding drum, bringing the bottom of the webbing to the top surface of the first feeding roller, passing it through the cleaning component, then bringing the top surface of the webbing to the bottom of one end of the support rod, passing it through one set of stabilizing mechanisms, then bringing the bottom of the front end of the webbing to the second feeding roller, passing it through the bottom of one side of the turning roller, and bringing the top surface of the webbing to the auxiliary roller, so that the bottom surface is facing upwards, thus turning the webbing over. Then, the front end of the webbing passes through the second set of stabilizing mechanisms, bringing the bottom surface of the webbing to the bottom of the support rod, and passing it through the bottom of the guide roller. The front end of the webbing is then fixed to the side of the take-up drum. By controlling the operation of the drive motor and the transmission toothed belt, the webbing is simultaneously unwound and rewounded. At the same time, the transmission toothed belt causes the cleaning component to brush off and collect the dust and debris adhering to the side of the webbing during the conveying process, until the entire roll of webbing is processed.

[0010] As a further improvement to the above solution, the stabilizing component consists of two sets of stabilizing mechanisms.

[0011] The stabilizing mechanism consists of two side plates, with a rotating roller and a contact roller rotatably connected to the opposite surfaces of the side plates.

[0012] The side of the braided belt is movably connected between the rotating roller and the contact roller.

[0013] Through the above technical solution, the woven belt passes through one set of stabilizing mechanisms during conveying, and after being flipped over, it passes through another set of stabilizing mechanisms for conveying, thereby improving the stability of woven belt conveying and retraction.

[0014] As a further improvement to the above solution, one of the side plates in the stabilizing mechanism is rotatably connected to the mounting panel.

[0015] With the above technical solution, one end of the two sets of stabilizing mechanisms is fixed, while one side plate of one set of stabilizing mechanisms is rotatably connected to the mounting panel, and can rotate to adjust the conveying direction according to the conveying path and thickness of the woven belt.

[0016] As a further improvement to the above solution, the feeding component includes a drive motor fixed to the back of the mounting panel and a feeding drum rotatably connected to the surface of the mounting panel. The output end of the drive motor passes through the mounting panel and is fixed on the axis of the feeding drum.

[0017] With the above technical solution, when the drive motor is running, the output end drives the unloading drum to rotate, thereby releasing the braided strip wound on the side outward.

[0018] As a further improvement to the above solution, the receiving component includes a rotating rod rotatably connected to the surface of the mounting panel, a rotating gear fixed at one end of the rotating rod, and a receiving drum fixed at one end of the rotating gear.

[0019] Through the above technical solution, the rotating rod plays a supporting role for the take-up drum, so that the take-up drum is aligned with the winding position of the braided belt.

[0020] As a further improvement to the above scheme, a transmission gear is fixed at one end of the feeding drum, and a transmission toothed belt meshes between the transmission gear and the rotating gear.

[0021] Through the above technical solution, the unloading drum drives the transmission gear to rotate simultaneously, and the transmission belt drives the take-up drum to rotate, so as to achieve the effect of synchronous rotation of the take-up drum and the unloading drum, avoid the woven belt from being pulled or loosened, and improve the stability of the woven belt conveyor.

[0022] As a further improvement to the above solution, the impurity removal component consists of an impurity removal cylinder, an impurity storage cylinder, and an air collection cylinder. The sides of the impurity removal cylinder are provided with interfaces, and the braided belt is movably connected within the interfaces.

[0023] The above technical solution allows the braided belt to enter through the interface above the impurity removal cylinder and exit through the interface at the bottom of the impurity removal cylinder, thereby improving the stability of the braided belt conveying.

[0024] As a further improvement to the above solution, the impurity removal cylinder is connected to the impurity storage cylinder, and a support frame is fixed at the connection. Connecting buttons are rotatably connected on the axis of both the support frame and the impurity removal cylinder, and torsion springs are installed at the axis positions.

[0025] A rotating plate is fixed to the side of the connecting button, and a peeling rod is rotatably connected to both ends of the rotating plate. A brush is provided on the side of the peeling rod along its length, and the brush is attached to the side of the woven belt.

[0026] With the above technical solution, the two ends of the torsion spring are respectively fixed between the connecting button and the corresponding support frame or impurity removal cylinder. Under the torsion of the torsion spring, the brushes on the peeling rods at both ends of the rotating plates adhere to the woven belt.

[0027] As a further improvement to the above solution, the miscellaneous storage cylinder is connected to the air collection cylinder, and a dustproof filter screen is fixed at the connection.

[0028] Through the above technical solution, when a negative pressure adsorption force is generated inside the air collection duct, the dust and debris brushed off by the brush are adsorbed. During adsorption, the dust filter prevents the dust and debris from entering the air collection duct, limiting the dust and debris to be stored only in the storage hopper.

[0029] As a further improvement to the above scheme, a rotating rod is rotatably connected inside the air collecting duct, a sleeve is fixed to the side of the rotating rod, and a fan blade is fixed to the side of the sleeve.

[0030] One end of the rotating rod is fixed to the connecting button on the support frame, while the other end is fixed to a rotating gear.

[0031] A connecting gear is fixed to one end of the rotating rod, and a transmission toothed belt meshes with the side of the connecting gear and the rotating gear.

[0032] With the above technical solution, when the rotating rod rotates, it drives the connecting gear to rotate. At this time, the toothed belt drives the rotating gear to rotate, thereby causing the fan blade to rotate and generate an adsorption force, thus sucking dust and debris into the storage cylinder.

[0033] Compared with the prior art, the present invention provides a main equipment for detecting the quality of webbing, which has the following beneficial effects:

[0034] 1. This main equipment for detecting the quality of webbing utilizes the positional structure design of multiple sets of rollers to control the bending state of the webbing. Through the coordinated transmission, the webbing is flipped from the front to the back during the conveying process for recycling, thus replacing the low efficiency problem of manual repeated flipping and inspection.

[0035] 2. The main equipment used for detecting the quality of webbing utilizes the cooperation of gears and toothed belts to achieve synchronous operation of the feeding drum and the take-up drum, thereby improving the stability of the webbing conveyor and avoiding the pulling or loosening of the webbing during the conveying process, further improving the safety and stability of the equipment operation.

[0036] 3. The main equipment for detecting the quality of webbing has a cleaning component on the output path of the webbing that cleans both sides of the webbing simultaneously. It uses a brush to remove debris attached to the surface of the webbing, and uses a take-up drum as a power source. With the transmission of gears and toothed belts, the fan blades rotate and generate suction force, thereby collecting the brushed debris into a storage drum. This improves cleaning efficiency, facilitates the collection of debris, and prevents it from scattering in the production workshop and affecting the indoor environment. Attached Figure Description

[0037] Figure 1This is a schematic diagram of the overall external structure of the device of this utility model;

[0038] Figure 2 This is a schematic diagram of the back structure of the mounting panel of this utility model;

[0039] Figure 3 This is a schematic diagram of the connection structure between the impurity removal component and the woven belt of this utility model;

[0040] Figure 4 This is a schematic diagram of the connection structure between the peeling rod and the braided belt of this utility model;

[0041] Figure 5 This is a schematic diagram of the cross-sectional connection structure between the impurity removal component and the woven belt of this utility model;

[0042] Figure 6 This is a schematic diagram of the connection structure between the fan blade and the rotating gear of this utility model;

[0043] Figure 7 This is a schematic diagram of the overall structure of the stabilizing mechanism of this utility model.

[0044] The attached diagram lists the components represented by each number as follows:

[0045] 1. Bracket;

[0046] 2. Mounting panel; 21. Feeding roller one; 22. Feeding roller two; 23. Turning roller; 24. Guide roller; 25. Auxiliary roller; 26. Stabilizing component; 261. Stabilizing mechanism; 2611. Side plate; 2612. Rotating roller; 2613. Contact roller; 27. Support rod;

[0047] 3. Feeding component; 301. Drive motor; 302. Feeding drum; 303. Transmission gear; 304. Transmission toothed belt; 305. Braided belt;

[0048] 4. Receiving component; 401. Rotating rod; 402. Rotating gear; 403. Receiving drum; 404. Connecting gear;

[0049] 5. Debris removal component; 51. Debris removal cylinder; 511. Interface; 512. Support frame; 513. Connecting button; 514. Rotating plate; 515. Peeling rod; 516. Brush; 517. Torsion spring; 52. Debris storage cylinder; 521. Dustproof filter; 53. Air collection duct; 531. Rotating rod; 532. Sleeve; 533. Fan blade; 534. Rotating gear; 535. Conductive toothed belt. Detailed Implementation

[0050] 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. Example

[0051] Please see Figures 1-7 As shown, the main equipment for detecting the quality of webbing proposed in this embodiment includes a bracket 1, a mounting panel 2, a feeding component 3, a receiving component 4, and a cleaning component 5. The mounting panel 2 is fixed on the bracket 1. Multiple rollers for assisting in turning the material over are provided on the surface of the mounting panel 2. Specifically, a first feeding roller 21 and a second feeding roller 22 are respectively provided at the two ends of the top of the mounting panel 2, and a turning roller 23 and a guide roller 24 are respectively provided at the two ends of the bottom of the mounting panel 2. The mounting panel 2 is fixed vertically on the bracket 1, so that the mounting panel 2 is perpendicular to the upper surface of the bracket 1. The first feeding roller 21 and the second feeding roller 22 are used to output the webbing 305, the turning roller 23 is used to turn the output webbing 305 over, and the guide roller 24 is used to guide the webbing 305 to be wound up.

[0052] The surface of the mounting panel 2 is provided with an auxiliary roller 25 and a stabilizing member 26 located between the second feeding roller 22 and the turning roller 23. The bottom of the braided belt 305 is attached to the side of the second feeding roller 22 and the front end of the braided belt 305 is guided to pass from the bottom of one side of the turning roller 23 to the other side. At this time, the top of the braided belt 305 is attached to the side of the auxiliary roller 25, so that the braided belt 305 can achieve the turning effect through the turning roller 23.

[0053] A support rod 27 is provided on the surface of the mounting panel 2 and between the feed roller 21 and the guide roller 24. The braided belt 305 is attached to the side of the support rod 27 during output and recycling, which improves the stability of the braided belt 305 conveying.

[0054] It should be further explained that the braided tape 305 is attached to the bottom of one end of the support rod 27 for output, and after being flipped, it is attached to the bottom of the other end of the support rod 27 for recycling.

[0055] The mounting panel 2 has a feeding component 3 and a receiving component 4 arranged opposite each other on one end. The feeding component 3 is movably connected to a braided belt 305, which is attached to multiple rollers and a stabilizing component 26. The front end of the braided belt 305 is movably connected to the receiving component 4. The feeding component 3 is used to output the braided belt 305 outward, and the receiving component 4 is used to recycle the output and flipped braided belt 305.

[0056] The surface of the mounting panel 2 is also equipped with a cleaning component 5 for cleaning dust and debris on the side of the braided belt 305. The cleaning component 5 is located between the feed roller 21 and the support rod 27. When the braided belt 305 is output, it is guided by the feed roller 21 through the cleaning component 5 and then adheres to the bottom of one end of the support rod 27, thereby completing the overall cleaning operation of the braided belt 305 while the braided belt 305 is continuously output.

[0057] The working principle of the main equipment for detecting the quality of webbing proposed in this embodiment is as follows: During use, by pulling the front end of the braided webbing 305 wound on the side of the unloading drum 302, the bottom of the braided webbing 305 is brought into contact with the top surface of the first feeding roller 21 and passes through the impurity removal component 5. Then, the top surface of the braided webbing 305 is brought into contact with the bottom of one end of the support rod 27 and passes through one of the stabilizing mechanisms 261. Next, the bottom of the front end of the braided webbing 305 is brought into contact with the second feeding roller 22 and passes through the bottom of one side of the turning roller 23 to the other side, bringing the top surface of the braided webbing 305 into contact with the auxiliary roller 25, with the bottom surface facing upwards, thus achieving the detection of the quality of the braided webbing. The 305 is flipped over, and the front end of the woven belt 305 is passed through the second set of stabilizing mechanisms 261. The top surface of the woven belt 305 is then attached to the bottom of the support rod 27 and passed through the bottom of the guide roller 24. The front end of the woven belt 305 is then fixed to the side of the take-up drum 403. The drive motor 301 is controlled to operate, and the woven belt 305 is simultaneously taken up and unloaded under the transmission of the transmission toothed belt 304. At the same time, the dust and debris attached to the side of the woven belt 305 during the conveying process is brushed off and collected by the transmission toothed belt 535 until the entire roll of woven belt 305 is processed. Example

[0058] Please see Figures 1-7 As shown, the host device for detecting the quality of webbing proposed in this embodiment, based on the first embodiment, further includes a stabilizing member 26 composed of two sets of stabilizing mechanisms 261.

[0059] The stabilizing mechanism 261 consists of two side plates 2611, with a rotating roller 2612 and a contact roller 2613 rotatably connected to the opposite surfaces of the side plates 2611.

[0060] The side of the braided belt 305 is movably connected between the rotating roller 2612 and the contact roller 2613.

[0061] More specifically, the braided belt 305 passes through one set of stabilizing mechanisms 261 during conveying, and after being flipped, it passes through another set of stabilizing mechanisms 261 for conveying, thereby improving the stability of the conveying and retraction of the braided belt 305.

[0062] It should be further explained that when the braided belt 305 is output, it passes through one set of stabilizing mechanisms 261, so that the top surface of the braided belt 305 is attached to the contact roller 2613 and the bottom surface is attached to the rotating roller 2612. When the braided belt 305 is retracted after being flipped, it passes through another set of stabilizing mechanisms 261, so that the top surface of the braided belt 305 is attached to the rotating roller 2612 and the bottom surface is attached to the contact roller 2613.

[0063] Furthermore, one of the side plates 2611 in the stabilizing mechanism 261 is rotatably connected to the mounting panel 2.

[0064] More specifically, one end of each of the two sets of stabilizing mechanisms 261 is fixed, while one of the side plates 2611 of one set of stabilizing mechanisms 261 is rotatably connected to the mounting panel 2, and can rotate to adjust the conveying direction according to the conveying path and thickness of the woven belt 305.

[0065] Furthermore, the feeding component 3 includes a drive motor 301 fixed to the back of the mounting panel 2, and a feeding drum 302 rotatably connected to the surface of the mounting panel 2. The output end of the drive motor 301 passes through the mounting panel 2 and is fixed on the axis of the feeding drum 302.

[0066] More specifically, when the drive motor 301 is in operation, the output end drives the unloading drum 302 to rotate, thereby releasing the braided strip 305 wound on the side outward.

[0067] Furthermore, the receiving component 4 includes a rotating rod 401 rotatably connected to the surface of the mounting panel 2, a rotating gear 402 fixed at one end of the rotating rod 401, and a receiving drum 403 fixed at one end of the rotating gear 402.

[0068] More specifically, the rotating rod 401 supports the take-up drum 403, aligning the take-up drum 403 with the take-up position of the braided belt 305.

[0069] Furthermore, a transmission gear 303 is fixed to one end of the feeding drum 302, and a transmission toothed belt 304 meshes between the transmission gear 303 and the rotating gear 402.

[0070] More specifically, the unloading drum 302 drives the transmission gear 303 to rotate simultaneously, and the transmission belt 304 drives the rotating gear 402 to rotate the take-up drum 403, so as to achieve the effect of synchronous rotation of the take-up drum 403 and the unloading drum 302, avoid the braided belt 305 from being pulled or loosened, and improve the stability of the braided belt 305 conveying.

[0071] Furthermore, the impurity removal component 5 consists of an impurity removal cylinder 51, an impurity storage cylinder 52, and an air collection cylinder 53. The side of the impurity removal cylinder 51 is provided with an interface 511, and the braided belt 305 is movably connected in the interface 511.

[0072] More specifically, the braided belt 305 is input from the interface 511 above the impurity removal cylinder 51 and output from the interface 511 at the bottom of the impurity removal cylinder 51, thereby improving the stability of the braided belt 305 conveying.

[0073] Furthermore, the impurity removal cylinder 51 is connected to the impurity storage cylinder 52, and a support frame 512 is fixed at the connection. A connecting button 513 is rotatably connected on the axis of both the support frame 512 and the impurity removal cylinder 51, and a torsion spring 517 is installed at the axis position.

[0074] A rotating plate 514 is fixed to the side of the connecting button 513. A peeling rod 515 is rotatably connected to both ends of the rotating plate 514. A brush 516 is provided on the side of the peeling rod 515 along its length. The brush 516 is attached to the side of the braided belt 305.

[0075] More specifically, the two ends of the torsion spring 517 are respectively fixed between the connecting button 513 and the corresponding support frame 512 or the impurity removal cylinder 51. Under the torsion of the torsion spring 517, the brushes 516 on the peeling rods 515 at both ends of the rotating plates 514 are attached to the braided belt 305.

[0076] Furthermore, the miscellaneous storage cylinder 52 is connected to the air collecting cylinder 53, and a dustproof filter 521 is fixed at the connection.

[0077] More specifically, when a negative pressure adsorption force is generated inside the air collecting duct 53, the dust and debris brushed off by the brush 516 are adsorbed. During adsorption, the dust filter 521 blocks the dust and debris from entering the air collecting duct 53, limiting the dust and debris to be stored only in the dust storage cylinder 52.

[0078] Furthermore, a rotating rod 531 is rotatably connected inside the air collecting duct 53, a sleeve 532 is fixed to the side of the rotating rod 531, and a fan blade 533 is fixed to the side of the sleeve 532.

[0079] One end of the rotating rod 531 is fixed to the connecting button 513 on the support frame 512, while the other end is fixed to the rotating gear 534.

[0080] One end of the rotating rod 401 is fixed with a connecting gear 404, and the connecting gear 404 and the side of the rotating gear 534 are meshed with a transmission toothed belt 535.

[0081] More specifically, when the rotating rod 401 rotates, it drives the connecting gear 404 to rotate. At this time, the toothed belt 535 drives the rotating gear 534 to rotate, thereby causing the fan blade 533 to rotate and generate an adsorption force, thus sucking dust and debris into the storage cylinder 52.

[0082] 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 main unit for detecting the quality of webbing, comprising a support (1), a mounting panel (2), a feeding component (3), a receiving component (4), and a cleaning component (5), characterized in that, The bracket (1) is fixed with a mounting panel (2). Multiple rollers for assisting material turning are provided on the surface of the mounting panel (2). Specifically, a first conveying roller (21) and a second conveying roller (22) are respectively provided at the two ends of the top of the mounting panel (2), and a turning roller (23) and a guide roller (24) are respectively provided at the two ends of the bottom of the mounting panel (2). An auxiliary roller (25) and a stabilizing member (26) are provided on the surface of the mounting panel (2) and between the feeding roller (22) and the turning roller (23). A support rod (27) is provided on the surface of the mounting panel (2) and between the feed roller (21) and the guide roller (24). The mounting panel (2) has a feeding component (3) and a receiving component (4) arranged opposite to each other on one end. A braided belt (305) is movably connected to the feeding component (3). The braided belt (305) is attached to multiple rollers and a stabilizing component (26), and its front end is movably connected to the receiving component (4). The surface of the mounting panel (2) is also equipped with a cleaning component (5) for cleaning dust and debris on the side of the braided belt (305).

2. The main equipment for detecting the quality of webbing according to claim 1, characterized in that: The stabilizing element (26) consists of two sets of stabilizing mechanisms (261); The stabilizing mechanism (261) consists of two side plates (2611), with a rotating roller (2612) and a contact roller (2613) rotatably connected to the opposite surfaces of the side plates (2611). The side of the braided tape (305) is movably connected between the rotating roller (2612) and the contact roller (2613).

3. The main equipment for detecting the quality of webbing according to claim 2, characterized in that: One of the side plates (2611) of the stabilizing mechanism (261) is rotatably connected to the mounting panel (2).

4. The main equipment for detecting the quality of webbing according to claim 1, characterized in that: The feeding component (3) includes a drive motor (301) fixed on the back of the mounting panel (2) and a feeding drum (302) rotatably connected to the surface of the mounting panel (2). The output end of the drive motor (301) passes through the mounting panel (2) and is fixed on the axis of the feeding drum (302).

5. The main equipment for detecting the quality of webbing according to claim 1, characterized in that: The receiving component (4) includes a rotating rod (401) rotatably connected to the surface of the mounting panel (2), a rotating gear (402) fixed at one end of the rotating rod (401), and a receiving drum (403) fixed at one end of the rotating gear (402).

6. The main equipment for detecting the quality of webbing according to claim 4, characterized in that: One end of the feeding drum (302) is fixed with a transmission gear (303), and a transmission toothed belt (304) meshes between the transmission gear (303) and the rotating gear (402).

7. The main equipment for detecting the quality of webbing according to claim 5, characterized in that: The impurity removal component (5) consists of an impurity removal cylinder (51), an impurity storage cylinder (52), and an air collection cylinder (53). The side of the impurity removal cylinder (51) is provided with an interface (511), and a braided belt (305) is movably connected in the interface (511).

8. The main equipment for detecting the quality of webbing according to claim 7, characterized in that: The impurity removal cylinder (51) is connected to the impurity storage cylinder (52), and a support frame (512) is fixed at the connection. A connecting button (513) is rotatably connected on the axis of the support frame (512) and the impurity removal cylinder (51), and a torsion spring (517) is installed at the axis position. A rotating plate (514) is fixed to the side of the connecting button (513). A peeling rod (515) is rotatably connected to both ends of the rotating plate (514). A brush (516) is provided on the side of the peeling rod (515) along its length. The brush (516) is attached to the side of the woven belt (305).

9. A main equipment for detecting the quality of webbing according to claim 8, characterized in that: The storage cylinder (52) is connected to the air collecting cylinder (53), and a dust filter (521) is fixed at the connection.

10. A main equipment for detecting the quality of webbing according to claim 9, characterized in that: A rotating rod (531) is rotatably connected inside the air collecting duct (53). A sleeve (532) is fixed on the side of the rotating rod (531), and a fan blade (533) is fixed on the side of the sleeve (532). One end of the rotating rod (531) is fixed to the connecting button (513) on the support frame (512), while the other end is fixed to a rotating gear (534). One end of the rotating rod (401) is fixed with a connecting gear (404), and the connecting gear (404) and the side of the rotating gear (534) are meshed with a transmission toothed belt (535).