A polyester filament winding device

By designing the control and drive components, the problem of uneven winding of polyester filaments was solved, achieving uniform winding of polyester filaments and improving the stability of the device, thus enhancing the practicality of the polyester filament winding device.

CN224429772UActive Publication Date: 2026-06-30HANGZHOU BOLIGE FIBER CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HANGZHOU BOLIGE FIBER CO LTD
Filing Date
2025-06-10
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Existing polyester filament winding devices can only wind polyester filaments in the same position, resulting in the polyester filaments not being evenly wound on the winding roller, which increases the limitations of the device.

Method used

By introducing control and drive components into the device, the slider, gears and motor work together to make the slider slide back and forth, so that the polyester filament is evenly wound on the winding roller. Rubber pads reduce wear, connecting rods limit the movement to improve stability, and the gear ratio design reduces the probability of excessive rotation.

Benefits of technology

This technology enables uniform winding of polyester filaments, reduces the limitations of the device, improves stability and practicality, and ensures tight winding of polyester filaments.

✦ Generated by Eureka AI based on patent content.

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Abstract

This application belongs to the technical field of winding devices and discloses a polyester filament winding device, including a base. Two symmetrical support plates are fixedly mounted on the upper surface of the base. A first motor is fixedly mounted on the side wall of one of the support plates. A rotating shaft is installed at the end of the output shaft of the first motor, and a winding roller is sleeved on the outer wall of the rotating shaft. A round rod is fixedly mounted on the adjacent side walls of the two support plates. A slider is sleeved on the outer wall of the round rod, and a perforated part is mounted on the slider. A control device for controlling the back-and-forth sliding of the slider is provided on the support plate. The control device includes a control component and a drive component. This application has the effect of reducing the limitations of the device.
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Description

Technical Field

[0001] This utility model relates to the field of winding device technology, and in particular to a polyester filament winding device. Background Technology

[0002] Polyester filament is a filament made of polyester, which is an important type of synthetic fiber. In order to facilitate the storage and use of polyester filament, a winding device is needed to wind the polyester filament.

[0003] When the winding device is in operation, the operator first places the winding roller on the rotating shaft, and then starts the motor to drive the rotating shaft to rotate. The rotating shaft drives the winding roller to rotate, so that the polyester filament is wound on the winding roller. However, when the winding device is in operation, it can only wind the polyester filament in the same position, which will result in the polyester filament not being evenly wound on the winding roller, thus increasing the limitations of the device. Utility Model Content

[0004] To solve the above problems, this utility model provides a polyester filament winding device.

[0005] The above-mentioned technical objective of this utility model is achieved through the following technical solution: a polyester filament winding device, including a base, two mutually symmetrical support plates are fixedly arranged on the upper surface of the base, a first motor is fixedly arranged on the side wall of one of the support plates, a rotating shaft is installed at the end of the output shaft of the first motor, a winding roller is sleeved on the outer wall of the rotating shaft, a round rod is fixedly arranged on the side walls of the two support plates that are close to each other, a slider is sleeved on the outer wall of the round rod, a perforated part is installed on the slider, and a control device for controlling the slider to slide back and forth is provided on the support plate. The control device includes a control component and a drive component.

[0006] By adopting the above technical solution, when workers need to wind polyester filaments, they pass one end of the polyester filament through the perforated part and fix it on the winding roller. Then, the workers need to start the first motor, causing its output shaft to rotate. This, in turn, causes the winding roller to rotate under the action of the motor's output shaft, thus winding the polyester filament onto the winding roller. During this process, the workers need to activate the control device to control the slider to slide back and forth, ensuring the polyester filament is evenly wound onto the winding roller, thereby reducing the limitations of the device.

[0007] Furthermore, a sliding groove is provided through one of the side walls of the support plate. The control component includes a connecting plate fixedly mounted on the side wall of the support plate, a slide rod slidably mounted in the sliding groove, a rack fixedly mounted on the side wall of the slide rod, a first semi-circular gear meshing with the rack, and a second semi-circular gear meshing with the rack. The first semi-circular gear and the second semi-circular gear are respectively mounted on both sides of the rack. The slide rod and the slider are fixed to each other.

[0008] Furthermore, the drive assembly includes a second motor fixedly mounted on the bottom surface of the connecting plate, a drive wheel fixedly mounted on the end of the output shaft of the second motor, a first driven wheel meshing with the drive wheel, and a second driven wheel meshing with the drive wheel. The first driven wheel is fixed to a first semi-circular gear, and the second driven wheel is fixed to a second semi-circular gear.

[0009] By adopting the above technical solution, when the operator needs to control the slider to slide back and forth, the operator needs to start the second motor, which in turn causes the output shaft of the second motor to rotate. This causes the driving wheel to rotate under the action of the output shaft of the second motor, which in turn causes the first driven wheel and the second driven wheel to rotate under the action of the driving wheel. This causes the first semi-circular gear and the second semi-circular gear to rotate under the action of the first driven wheel and the second driven wheel, respectively. In this process, the… Figure 1 As shown, when the rack meshes with the first semi-circular gear, the rack moves under the action of the first semi-circular gear, which in turn causes the slide bar to slide under the action of the rack, thus causing the slider to slide under the action of the slide bar. Subsequently, when the rack disengages from the first semi-circular gear, the rack meshes with the second semi-circular gear, which causes the rack to move in the opposite direction under the action of the first semi-circular gear, which in turn causes the slide bar to slide in the opposite direction under the action of the rack, thus causing the slider to slide in the opposite direction under the action of the slide bar. During this process, the slider slides back and forth, thereby ensuring that the polyester filament is evenly wound onto the winding roller, thus reducing the limitations of the device.

[0010] Furthermore, two mounting slots are symmetrically formed on the upper surface of the connecting plate, and bearings are provided in both mounting slots. Connecting rods are fixedly provided on the bottom surfaces of the first driven wheel and the second driven wheel, and the inner rings of the bearings of the connecting rods are fixed to each other.

[0011] By adopting the above technical solution, when the first driven wheel and the second driven wheel rotate, the connecting rod rotates under the action of the first driven wheel and the second driven wheel, thereby causing the inner ring of the bearing to rotate under the action of the connecting rod. During this process, the connecting rod and the bearing limit the first driven wheel and the second driven wheel, thereby reducing the probability of the first driven wheel and the second driven wheel separating from the driving wheel, thus improving the stability of the device.

[0012] Furthermore, an installation plate is fixedly provided on the upper surface of the support plate, and a limit rod is fixedly provided on the side wall of the rack away from the slide rod. The limit rod passes through the installation plate and is slidably connected to the installation plate.

[0013] By adopting the above technical solution, the limiting rod supports the side of the rack away from the slide bar, thereby improving the stability of the rack during sliding and thus improving the stability of the device.

[0014] Furthermore, a rubber pad is fixedly provided on the inner wall of the perforated component.

[0015] By adopting the above technical solution, the rubber pad reduces the probability of wear on the polyester filaments when they move inside the perforated part, thereby improving the practicality of the device.

[0016] Furthermore, tension rollers are installed on the sidewalls of the two support plates that are close to each other.

[0017] By adopting the above technical solution, when workers need to wind polyester filaments, they pass one end of the polyester filament through the lower end of the tension roller and fix it on the winding roller through the perforated part. In this process, the tightness of the polyester filament winding is improved.

[0018] Furthermore, the gear ratio between the first driven gear and the second driven gear and the driving gear is 10:1.

[0019] By adopting the above technical solution, when the driving wheel rotates 10 times, the first driven wheel and the second driven wheel only rotate once, thereby reducing the probability of the polyester filaments becoming too scattered due to the driving wheel rotating too fast, thus improving the practicality of the device.

[0020] In summary, this utility model has the following beneficial effects:

[0021] 1. In this application, when the operator needs to wind the polyester filament, the operator passes one end of the polyester filament through the perforated part and fixes it on the winding roller. Subsequently, the operator needs to start the first motor, which causes the output shaft of the first motor to rotate, thereby causing the winding roller to rotate under the action of the output shaft of the first motor, and thus causing the polyester filament to wind onto the winding roller. During this process, the operator needs to activate the control device to control the slider to slide back and forth, thereby making the polyester filament evenly wound onto the winding roller, thus reducing the limitations of the device;

[0022] 2. In this application, when the operator needs to control the slider to slide back and forth, the operator needs to start the second motor, which in turn causes the output shaft of the second motor to rotate. This causes the driving wheel to rotate under the action of the output shaft of the second motor, which in turn causes the first driven wheel and the second driven wheel to rotate under the action of the driving wheel. This causes the first semi-circular gear and the second semi-circular gear to rotate under the action of the first driven wheel and the second driven wheel, respectively. In this process, by Figure 1As shown, when the rack meshes with the first semi-circular gear, the rack moves under the action of the first semi-circular gear, which in turn causes the slide bar to slide under the action of the rack, thereby causing the slider to slide under the action of the slide bar. Subsequently, when the rack disengages from the first semi-circular gear, the rack meshes with the second semi-circular gear, which causes the rack to move in the opposite direction under the action of the first semi-circular gear, which in turn causes the slide bar to slide in the opposite direction under the action of the rack, thereby causing the slider to slide in the opposite direction under the action of the slide bar. During this process, the slider slides back and forth, thereby making the polyester filament evenly wound onto the winding roller, thus reducing the limitations of the device.

[0023] 3. In this application, when the first driven wheel and the second driven wheel rotate, the connecting rod rotates under the action of the first driven wheel and the second driven wheel, thereby causing the inner ring of the bearing to rotate under the action of the connecting rod. During this process, the connecting rod and the bearing limit the first driven wheel and the second driven wheel, thereby reducing the probability of the first driven wheel and the second driven wheel separating from the driving wheel, thus improving the stability of the device. Attached Figure Description

[0024] Figure 1 This is a schematic diagram of the overall structure of an embodiment of the present utility model;

[0025] Figure 2 This is a schematic diagram of the structure of the control component in an embodiment of this utility model;

[0026] Figure 3 This is a schematic diagram of the structure of the driving component in an embodiment of this utility model;

[0027] Figure 4 This is a cross-sectional structural diagram of the driving component in an embodiment of this utility model.

[0028] In the diagram: 1. Base; 11. Support plate; 12. First motor; 13. Winding roller; 14. Round rod; 15. Slider; 16. Perforated part; 2. Slide groove; 3. Control component; 31. Connecting plate; 32. Slide rod; 33. Rack; 34. First semi-circular gear; 35. Second semi-circular gear; 4. Drive component; 41. Second motor; 42. Driving wheel; 43. First driven wheel; 44. Second driven wheel; 5. Mounting groove; 51. Bearing; 52. Connecting rod; 6. Mounting plate; 61. Limiting rod; 7. Tension roller. Detailed Implementation

[0029] The technical solutions in the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, and not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of this application without creative effort are within the scope of protection of this application.

[0030] like Figure 1-4 As shown in the figure, this application discloses a polyester filament winding device, including a base 1, a support plate 11, a first motor 12, a winding roller 13, a round rod 14, a slider 15, a perforated part 16, a control component 3, a drive component 4, a bearing 51, a connecting rod 52, a mounting plate 6, and a limiting rod 61. The base 1 is a rectangular plate structure, and the support plate 11 is a rectangular plate structure. Two support plates 11 are provided and symmetrically arranged on the upper surface of the base 1. The first motor 12 is fixedly mounted on the side wall of one of the support plates 11, and its axis coincides with the axis of the output shaft of the first motor 12. A rotating shaft (not shown in the figure) is mounted on the end of the output shaft of the first motor 12, and its axis coincides with the axis of the output shaft of the first motor 12. The winding roller 13 is sleeved on the outer wall of the rotating shaft, and its axis coincides with the axis of the output shaft of the first motor 12. The round rod 14 is a round rod structure with a horizontal axis, and the round rod 14 is fixedly mounted on the side walls of the two support plates 11 that are close to each other. The slider 15 is a rectangular block structure, which is sleeved on the outer wall of the round rod 14. The perforated part 16 is installed on the slider 15. The control device is set on the support plate 11 and is used to control the slider 15 to slide back and forth. The control device includes a control component 3 and a drive component 4.

[0031] When the operator needs to wind the polyester filament, one end of the polyester filament is passed through the perforated part 16 and fixed to the winding roller 13. Then, the operator needs to start the first motor 12, which causes the output shaft of the first motor 12 to rotate, thereby causing the winding roller 13 to rotate under the action of the output shaft of the first motor 12, and thus the polyester filament is wound onto the winding roller 13. During this process, the operator needs to activate the control device to control the slider 15 to slide back and forth, so that the polyester filament is evenly wound onto the winding roller 13, thereby reducing the limitations of the device.

[0032] A groove 2 is formed through the side wall of one of the support plates 11. The control component 3 includes a connecting plate 31, a slide rod 32, a rack 33, a first semi-circular gear 34, and a second semi-circular gear 35. The connecting plate 31 is a rectangular plate structure and is fixedly mounted on the side wall of the support plate 11. The slide rod 32 is a rectangular rod structure and is slidably mounted in the groove 2. The slide rod 32 is fixed to the slider 15. The rack 33 is fixedly mounted on the side wall of the slide rod 32. The first semi-circular gear 34 meshes with the rack 33, and the second semi-circular gear 35 meshes with the rack 33. The first semi-circular gear 34 and the second semi-circular gear 35 are respectively located on both sides of the rack 33.

[0033] The drive assembly 4 includes a second motor 41, a driving wheel 42, a first driven wheel 43, and a second driven wheel 44. The second motor 41 is fixedly mounted on the bottom surface of the connecting plate 31, and its output shaft axis is vertical. The driving wheel 42 is fixedly mounted at the end of the output shaft of the second motor 41, and its axis coincides with the axis of the output shaft of the second motor 41. The first driven wheel 43 meshes with the driving wheel 42, and the first driven wheel 43 is fixed to the first semi-circular gear 34. The second driven wheel 44 meshes with the driving wheel 42, and the second driven wheel 44 is fixed to the second semi-circular gear 35.

[0034] When the operator needs to control the slider 15 to slide back and forth, the operator needs to start the second motor 41, which in turn causes the output shaft of the second motor 41 to rotate. This causes the driving wheel 42 to rotate under the action of the output shaft of the second motor 41, which in turn causes the first driven wheel 43 and the second driven wheel 44 to rotate under the action of the driving wheel. This causes the first semi-circular gear 34 and the second semi-circular gear 35 to rotate under the action of the first driven wheel 43 and the second driven wheel 44, respectively. In this process, the… Figure 1 As shown, when the rack 33 meshes with the first semi-circular gear 34, the rack 33 moves under the action of the first semi-circular gear 34, which in turn causes the slide bar 32 to slide under the action of the rack 33, thereby causing the slider 15 to slide under the action of the slide bar 32. Subsequently, when the rack 33 separates from the first semi-circular gear 34, the rack 33 meshes with the second semi-circular gear 35, which in turn causes the rack 33 to move in the opposite direction under the action of the first semi-circular gear 34, which in turn causes the slide bar 32 to slide in the opposite direction under the action of the rack 33, thereby causing the slider 15 to slide in the opposite direction under the action of the slide bar 32. During this process, the slider 15 slides back and forth, thereby making the polyester filament evenly wound onto the winding roller 13, thus reducing the limitations of the device.

[0035] The upper surface of the connecting plate 31 has two symmetrical mounting grooves 5. Two bearings 51 are provided and installed in the two mounting grooves 5 respectively. The connecting rod 52 is a round rod 14 structure. Two connecting rods 52 are provided and fixedly installed on the bottom surfaces of the first driven wheel 43 and the second driven wheel 44 respectively. The inner rings of the connecting rods 52 and bearings 51 are fixed to each other.

[0036] When the first driven wheel 43 and the second driven wheel 44 rotate, the connecting rod 52 rotates under the action of the first driven wheel 43 and the second driven wheel 44, thereby causing the inner ring of the bearing 51 to rotate under the action of the connecting rod 52. During this process, the connecting rod 52 and the bearing 51 limit the first driven wheel 43 and the second driven wheel 44, thereby reducing the probability of the first driven wheel 43 and the second driven wheel 44 separating from the driving wheel 42, thus improving the stability of the device.

[0037] Mounting plate 6 is a rectangular plate structure and is fixedly mounted on the upper surface of support plate 11. Limiting rod 61 is a rectangular rod structure and is fixedly mounted on the side wall of rack 33 away from slide rod 32. Limiting rod 61 passes through mounting plate 6 and is slidably connected to mounting plate 6.

[0038] The limiting rod 61 supports the side of the rack 33 away from the slide rod 32, thereby improving the stability of the rack 33 during sliding and thus improving the stability of the device.

[0039] To improve the practicality of the device, a rubber pad is fixedly installed on the inner wall of the perforated part 16. The rubber pad reduces the probability of wear and tear on the polyester filaments as they move within the perforated part 16, thereby improving the practicality of the device.

[0040] To improve the tightness of polyester filament winding, tension rollers 7 are installed on the side walls of the two support plates 11 that are close to each other. When the operator needs to wind the polyester filament, the operator passes one end of the polyester filament through the lower end of the tension roller 7 and fixes it to the winding roller 13 through the perforated part 16. In this process, the tightness of the polyester filament winding is improved.

[0041] To improve the practicality of the device, the gear ratio between the first driven wheel 43 and the second driven wheel 44 and the driving wheel 42 is 10:1. When the driving wheel 42 rotates 10 times, the first driven wheel 43 and the second driven wheel 44 rotate only once, thereby reducing the probability that the polyester filaments will become too scattered due to the driving wheel 42 rotating too fast, thus improving the practicality of the device.

[0042] The working principle of the polyester filament winding device in this embodiment is as follows: When the operator needs to wind the polyester filament, one end of the polyester filament is passed through the perforated part 16 and fixed on the winding roller 13. Subsequently, the operator needs to start the first motor 12, which causes the output shaft of the first motor 12 to rotate, thereby causing the winding roller 13 to rotate under the action of the output shaft of the first motor 12, thus winding the polyester filament onto the winding roller 13. During this process, the operator needs to activate the control device to control the slider 15 to slide back and forth, thereby making the polyester filament evenly wound onto the winding roller 13, thus reducing the limitations of the device.

[0043] The above description is merely a preferred embodiment of this utility model. The protection scope of this utility model is not limited to the above embodiments. All technical solutions falling within the scope of this utility model's concept are protected. It should be noted that for those skilled in the art, any improvements and modifications made without departing from the principle of this utility model should also be considered within the protection scope of this utility model.

Claims

1. A polyester filament winding device comprising a base (1), characterized in that: Two symmetrical support plates (11) are fixedly mounted on the upper surface of the base (1). A first motor (12) is fixedly mounted on the side wall of one of the support plates (11). A rotating shaft is installed at the end of the output shaft of the first motor (12). A winding roller (13) is sleeved on the outer wall of the rotating shaft. A round rod (14) is fixedly mounted on the side walls of the two support plates (11) that are close to each other. A slider (15) is sleeved on the outer wall of the round rod (14). A perforated part (16) is installed on the slider (15). A control device for controlling the slider (15) to slide back and forth is provided on the support plate (11). The control device includes a control component (3). The control component (3) includes a connecting plate (31) fixedly mounted on the side wall of the support plate (11), a slide rod (32) slidably mounted in the slide groove (2), a rack (33) fixedly mounted on the side wall of the slide rod (32), a first semi-circular gear (34) meshing with the rack (33), and a second semi-circular gear (35) meshing with the rack (33). The first semi-circular gear (34) and the second semi-circular gear (35) are respectively mounted on both sides of the rack (33). The slide rod (32) and the slider (15) are fixed to each other.

2. The polyester filament winding device according to claim 1, characterized in that: The drive assembly (4) includes a second motor (41) fixedly mounted on the bottom surface of the connecting plate (31), a drive wheel (42) fixedly mounted on the end of the output shaft of the second motor (41), a first driven wheel (43) meshing with the drive wheel (42), and a second driven wheel (44) meshing with the drive wheel (42). The first driven wheel (43) is fixed to the first semi-circular gear (34), and the second driven wheel (44) is fixed to the second semi-circular gear (35).

3. The polyester filament winding device according to claim 2, characterized in that: The upper surface of the connecting plate (31) has two symmetrical mounting grooves (5), and each of the two mounting grooves (5) is provided with a bearing (51). The bottom surfaces of the first driven wheel (43) and the second driven wheel (44) are both fixedly provided with a connecting rod (52), and the inner ring of the connecting rod (52) and the bearing (51) are fixed to each other.

4. The polyester filament winding device according to claim 1, characterized in that: An mounting plate (6) is fixedly provided on the upper surface of the support plate (11). A limiting rod (61) is fixedly provided on the side wall of the rack (33) away from the slide rod (32). The limiting rod (61) passes through the mounting plate (6) and is slidably connected to the mounting plate (6).

5. The polyester filament winding device according to claim 1, characterized in that: A rubber pad is fixedly installed on the inner wall of the perforated part (16).

6. The polyester filament winding device according to claim 1, characterized in that: Tension rollers (7) are installed together on the side walls of the two support plates (11) that are close to each other.

7. The polyester filament winding device according to claim 2, characterized in that: The gear ratio of the first driven gear (43) and the second driven gear (44) to the driving gear (42) is 10:1.