Multi-point waste silk automatic collection and processing system

By using a servo motor-driven swing assembly and a dust suction head design, the problems of tangled waste filaments and difficulty in angle adjustment in traditional waste filament collection devices are solved, achieving efficient and flexible waste filament collection and processing.

CN224487026UActive Publication Date: 2026-07-14JIAXING GUANGYUE ENVIRONMENTAL ENG EQUIP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIAXING GUANGYUE ENVIRONMENTAL ENG EQUIP CO LTD
Filing Date
2025-07-01
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Traditional automatic waste filament collection and processing devices are prone to tangling and knotting during collection, and it is difficult to adjust the suction angle, resulting in some waste filaments being difficult to collect. In addition, the equipment is bulky and difficult to adjust its position, which reduces collection efficiency and applicability.

Method used

The system employs a multi-point automatic waste filament collection and processing system. It uses a servo motor-driven swing assembly and a swiveling suction head to collect waste filaments. Combined with a filter screen and casters, it achieves multi-angle collection of waste filaments and flexible movement of the equipment.

Benefits of technology

It effectively prevents waste filaments from tangling, improves collection efficiency, enhances the applicability and flexibility of the equipment, and ensures effective collection of waste filaments in different environments.

✦ Generated by Eureka AI based on patent content.

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    Figure CN224487026U_ABST
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Abstract

The utility model relates to the technical field of collection waste silk processing device, especially to the multi -point waste silk automatic collection processing system, including work table and separation tank, separation tank installs in the lateral wall of work table, is equipped with support frame on work table, is equipped with servo motor on work table, servo motor end part is equipped with swing assembly, work table end part is equipped with second axle table symmetrically. The utility model discloses through setting swing assembly, through the swing of limiting ring of L -shaped rod drive, makes the dust absorption head to waste silk and swing collection, prevents due to the suction of fixed angle, produces the situation that waste silk produces knot, leads to mechanical failure, influences the work efficiency of subsequent collection waste silk, through setting filter screen, the dust in waste silk is down through filter screen, and the operator is convenient to the collection treatment of waste, through setting servo motor, the operator is convenient to adjust the angle of dust absorption head, improves the work efficiency of equipment facing different waste silk collection, improves the applicability of equipment.
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Description

Technical Field

[0001] This utility model relates to the technical field of waste filament collection and treatment devices, and in particular to a multi-point automatic waste filament collection and treatment system. Background Technology

[0002] Waste filaments typically refer to waste filamentous materials generated during the production process in industries such as textiles, chemical fibers, metal processing, and electronics. In the textile industry, waste filaments also contain materials such as dust and waste yarn, requiring collection and processing equipment to recycle and reprocess them.

[0003] Traditional automatic waste filament collection and processing devices often suffer from problems during collection. The filaments tend to become knotted and tangled, leading to mechanical malfunctions and reduced efficiency. Furthermore, the difficulty in adjusting the suction angle limits the collection of some filaments, resulting in the majority being sucked in at a fixed angle, leaving the rest uncollected. Additionally, the bulkiness of these devices makes them difficult to adjust, resulting in low applicability. Utility Model Content

[0004] The purpose of this invention is to solve the problem in the existing technology where the vacuum head sucks in waste filaments at a fixed angle, making it difficult to collect and process the remaining waste filaments. Therefore, a multi-point automatic waste filament collection and processing system is proposed.

[0005] To achieve the above objectives, the present invention adopts the following technical solution:

[0006] A multi-point automatic waste filament collection and processing system includes a workbench and a separation box. The separation box is installed on the side wall of the workbench. A support frame is provided on the workbench. A servo motor is provided on the workbench. A swing component is provided at the end of the servo motor. A second shaft is symmetrically provided at the end of the workbench. A third rotating shaft is coaxially provided on the second shaft. A full gear is provided at the end of the third rotating shaft. A vacuum head is symmetrically provided on the third rotating shaft. A hose is inserted at the end of the vacuum head. The other end of the hose is inserted into the end of the separation box. A vacuum pump is provided on the hose. A filter screen is also provided inside the separation box. Universal wheels are provided around the bottom of the workbench.

[0007] Preferably, a third shaft platform is fixedly provided at the end of the support frame, a first rotating shaft is coaxially rotatably provided on the inner side wall of the third shaft platform, and the end of the first rotating shaft is fixedly connected to the output end of the servo motor. A first shaft platform is fixedly provided at the top of the support frame, and a second rotating shaft is coaxially rotatably provided on the inner side wall of the third shaft platform.

[0008] Preferably, the swing assembly includes a limiting ring and a half gear. The limiting ring is coaxially fixedly disposed on the outer side wall of the second rotating shaft, and the half gear is coaxially fixedly disposed at the end of the second rotating shaft, and the half gear meshes with the full gear.

[0009] Preferably, the swing assembly further includes an L-shaped rod, which is coaxially fixed at the end of the first rotating shaft, and the end of the L-shaped rod is connected to the inner sidewall of the limiting ring.

[0010] Preferably, the outer wall of the third rotating shaft is symmetrically provided with fixing plates, and the end of the fixing plates is fixedly connected to the end of the vacuum head.

[0011] Preferably, the separation box is provided with a sealing plate via a hinge, the sealing plate is provided with a handle, and the end of the separation box is also provided with a blower.

[0012] Compared with the prior art, the present invention has the following advantages:

[0013] 1. This utility model uses a swing assembly, where an L-shaped rod drives a limiting ring to swing, allowing the suction head to swing and collect waste filaments. This prevents the waste filaments from getting tangled due to a fixed angle of suction, which could cause mechanical malfunctions and affect the efficiency of subsequent waste filament collection.

[0014] 2. This utility model incorporates a filter screen, allowing dust in the waste filaments to fall through the screen, facilitating waste collection and processing by operators. The inclusion of a servo motor allows operators to easily adjust the angle of the suction head, improving the equipment's efficiency in collecting different types of waste filaments and enhancing its applicability. Attached Figure Description

[0015] Figure 1 This is an isometric view of the multi-point waste filament automatic collection and processing system proposed in this utility model;

[0016] Figure 2 These are the left and right isometric views of the multi-point waste filament automatic collection and processing system proposed in this utility model;

[0017] Figure 3 A partial schematic diagram (A) shows the multi-point automatic waste filament collection and processing system proposed in this utility model.

[0018] Figure 4 This is a partial cross-sectional schematic diagram of the multi-point waste filament automatic collection and processing system proposed in this utility model.

[0019] In the diagram: 1. Workbench; 2. First rotating axis; 3. Servo motor; 4. Support frame; 5. First shaft platform; 6. Second rotating axis; 7. Limit ring; 8. Half gear; 9. Full gear; 10. Dust suction head; 11. Fixing plate; 12. Hose; 13. Dust pump; 14. Third rotating axis; 15. Second shaft platform; 16. Casters; 17. Blower; 18. Sealing plate; 19. Handle; 20. Separation box; 21. Third shaft platform; 22. L-shaped rod; 23. Filter screen. Detailed Implementation

[0020] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments.

[0021] Reference Figures 1-4 The multi-point waste filament automatic collection and processing system, also known as the multi-point waste filament automatic collection and processing device, includes a workbench 1 and a separation box 20. The separation box 20 is fixedly installed on the side wall of the workbench 1 by bolt assembly. The support frame 4 is fixedly installed on the end of the workbench 1 by bolt assembly. The servo motor 3 is fixedly installed on the side wall of the workbench 1 by bolt assembly. A shock-absorbing pad is provided between the servo motor 3 and the workbench 1. A servo controller is provided on the servo motor 3. Through the operation program of the servo controller, the rotation direction and rotation angle of the output end of the servo motor 3 are adjusted to effectively control the direction of rotation and provide driving force for the first rotating shaft 2. This operation program is existing technology and will not be elaborated on here.

[0022] like Figure 3 As shown, the third axis platform 21 is fixedly mounted on the end of the support frame 4 by bolt assembly. The first rotating shaft 2 is rotatably mounted on the inner wall of the third axis platform 21 by rotating assembly, and the end of the first rotating shaft 2 is fixedly connected to the output end of the servo motor 3 by clamping sleeve. The first axis platform 5 is fixedly mounted on the top of the support frame 4 by bolt assembly. The second rotating shaft 6 is rotatably mounted on the inner wall of the third axis platform 21 by rotating assembly. This configuration provides power transmission for the third rotating shaft 14 and improves the stability during rotation.

[0023] The second shaft platform 15 is symmetrically fixed at the end of the worktable 1 by bolt assembly. The third rotating shaft 14 is rotatably mounted on the inner side wall of the second shaft platform 15 by rotating assembly, and the end of the third rotating shaft 14 extends into the support frame 4. The full gear 9 is fixed at the end of the third rotating shaft 14 by key. This configuration provides power transmission for the third rotating shaft 14.

[0024] The servo motor 3 is equipped with a swing assembly at its end. The swing assembly includes a limit ring 7 and a half gear 8. The limit ring 7 is coaxially fixed to the outer side wall of the second rotating shaft 6 by a clamping sleeve. The support frame 4 has a groove. This arrangement prevents the limit ring 7 from malfunctioning due to insufficient rotation space, which would affect the subsequent work efficiency.

[0025] The half gear 8 is coaxially fixed at the end of the second rotating shaft 6 by a key, and the half gear 8 meshes with the full gear 9. The diameter of the half gear 8 is larger than the diameter of the full gear 9. When the second rotating shaft 6 rotates, the second rotating shaft 6 drives the half gear 8 to rotate, and the half gear 8 drives the full gear 9 to swing. This arrangement ensures the stability of the overall component during operation.

[0026] The swing assembly also includes an L-shaped rod 22, which is coaxially fixed at the end of the first rotating shaft 2 via a clamping sleeve. The end of the L-shaped rod 22 is connected to the inner wall of the limiting ring 7. The rotation of the first rotating shaft 2 causes the L-shaped rod 22 to rotate around the first rotating shaft 2, causing the L-shaped rod 22 to drive the limiting ring 7 to swing. The limiting ring 7 drives the second rotating shaft 6 to rotate, the second rotating shaft 6 drives the half gear 8 to rotate, and the half gear 8 drives the full gear 9 to rotate. This configuration provides driving force to the third rotating shaft 14. By swinging the suction head 10 back and forth, the efficiency of waste filament collection is improved. The direction of rotation and the frequency of swing are adjusted by the servo motor 3 to adapt to different waste filament environments and prevent the collection efficiency of waste filament from being affected by the difficulty in adjusting the angle of the suction head 10.

[0027] The third rotating shaft 14 is symmetrically provided with suction heads 10. The fixing plate 11 is symmetrically provided on the outer wall of the third rotating shaft 14 by bolt assembly. The end of the fixing plate 11 is fixedly connected to the end of the suction head 10. This arrangement prevents the suction head 10 from falling off during operation, affecting the overall operation of the machine and causing economic damage.

[0028] One end of the hose 12 is inserted into the end of the vacuum head 10, and the other end of the hose 12 is inserted into the end of the separation box 20. The hose 12 is connected to the vacuum head 10. The vacuum pump 13 is fixedly mounted on the outer wall of the hose 12 by a bolt assembly. This arrangement improves the power of the vacuum head when collecting waste filaments.

[0029] The sealing plate 18 is hinged to the end of the separation box 20, the handle 19 is fixed to the end of the sealing plate 18 by bolt assembly, the blower 17 is fixed to the end of the separation box 20 by bolt assembly, and the blower 17 is connected to the hose 12, the filter screen 23 is fixed to the inner wall of the separation box 20 by bolt assembly, and multiple casters 16 are fixed to the bottom of the workbench 1 around the perimeter by bolt assembly.

[0030] It should be noted that the suction head 10 sucks in the waste filaments, which then enter the separation box 20 through the suction pump 13 and the hose 12. The blower 17 blows the waste filaments through the filter screen 23, which filters the dust in the waste filaments. The operator opens the sealing plate 18 through the handle 19 to centrally process the waste filaments in the separation box 20. The universal wheels 16 facilitate the movement of the waste filament collection and processing device by the operator.

[0031] The aforementioned bolt assembly and rotating assembly are both existing technologies. The bolt assembly includes a bolt and a threaded hole for threading two components together. The rotating assembly includes a rotating groove, an annular block, and an annular groove. The annular groove is formed on the inner wall of the rotating groove, and the annular block rotates within the annular groove.

[0032] The functional principle of this utility model can be explained through the following operation methods:

[0033] Servo motor 3 drives the first rotating shaft 2 to rotate, the first rotating shaft 2 drives the L-shaped rod 22 to rotate, the limiting ring 7 is connected to the end of the L-shaped rod 22, the L-shaped rod 22 drives the limiting ring 7 to swing, the limiting ring 7 drives the second rotating shaft 6 to swing, the second rotating shaft 6 drives the half gear 8 to swing, the half gear 8 meshes with the full gear 9, the full gear 9 drives the third rotating shaft 14 to swing, the third rotating shaft 14 drives multiple fixed plates 11 to swing, and the fixed plates 11 drive the vacuum cleaner 10 to swing.

[0034] Drive the vacuum pump 13, and the waste filaments enter the separation box 20 through the vacuum head 10 and the hose 12. Drive the blower 17 to filter the dust in the waste filaments through the filter screen 23. The operator opens the sealing plate 18 to collect and process the waste filaments in the separation box 20.

[0035] The above description is only a preferred embodiment of the present utility model, but the protection scope of the present utility model is not limited thereto. Any equivalent substitutions or changes made by those skilled in the art within the technical scope disclosed in the present utility model, based on the technical solution and the inventive concept of the present utility model, should be included within the protection scope of the present utility model.

Claims

1. A multi-point automatic waste filament collection and processing system, comprising a workbench and a separation box, wherein the separation box is installed on the side wall of the workbench, characterized in that, The workbench is equipped with a support frame and a servo motor. The end of the servo motor is equipped with a swing component. A second axis is symmetrically located at the end of the workbench. A third rotating axis is coaxially located on the second axis. A full gear is located at the end of the third rotating axis. A dust suction head is symmetrically located on the third rotating axis, and a hose is inserted into the end of the dust suction head. The other end of the hose is inserted into the end of the separation box. A dust pump is located on the hose. A filter screen is also located inside the separation box. Universal wheels are located around the bottom of the workbench.

2. The multi-point waste filament automatic collection and processing system according to claim 1, characterized in that, A third shaft platform is fixedly provided at the end of the support frame. A first rotating shaft is coaxially rotatably provided on the inner side wall of the third shaft platform, and the end of the first rotating shaft is fixedly connected to the output end of the servo motor. A first shaft platform is fixedly provided on the top of the support frame, and a second rotating shaft is coaxially rotatably provided on the inner side wall of the third shaft platform.

3. The multi-point waste filament automatic collection and processing system according to claim 2, characterized in that, The swing assembly includes a limiting ring and a half gear. The limiting ring is coaxially fixedly disposed on the outer side wall of the second rotating shaft, and the half gear is coaxially fixedly disposed at the end of the second rotating shaft, and the half gear meshes with the full gear.

4. The multi-point waste filament automatic collection and processing system according to claim 3, characterized in that, The swing assembly also includes an L-shaped rod, which is coaxially fixed at the end of the first rotating shaft, and the end of the L-shaped rod is connected to the inner wall of the limiting ring.

5. The multi-point waste filament automatic collection and processing system according to claim 4, characterized in that, The outer wall of the third rotating shaft is symmetrically provided with fixing plates, and the end of the fixing plates is fixedly connected to the end of the vacuum head.

6. The multi-point waste filament automatic collection and processing system according to claim 5, characterized in that, The separator is equipped with a sealing plate via a hinge, and the sealing plate has a handle. A blower is also provided at the end of the separator.