High-elasticity composite yarn winding machine
By introducing a cleanup mechanism into the winding machine, using brushes and a fan filter assembly to clean impurities from the yarn, the problem of poor yarn quality during the winding process is solved, achieving a high-quality yarn winding effect.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SUZHOU LINGXIAN NEW MATERIAL TECH CO LTD
- Filing Date
- 2025-08-26
- Publication Date
- 2026-07-14
AI Technical Summary
When using existing winding machines, impurities easily adhere to the yarn on the bobbin, resulting in poor quality of the high-elastic composite yarn winding product and affecting subsequent processes.
A high-elastic composite yarn winding machine was designed, equipped with a cleanup mechanism, including a cleaning box, brush bristles, sealing rings, yarn inlet, discharge outlet, and filter assembly. The brush bristles clean impurities from the yarn, and the blower and filter screen filter impurities to ensure that the yarn is clean before winding.
This improved the quality of the yarn after winding, reduced defects in subsequent processes, and ensured the cleanliness of the yarn and the quality of the finished product.
Smart Images

Figure CN224493259U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of high-elastic composite yarn winding technology, specifically a winding machine for high-elastic composite yarn. Background Technology
[0002] High-elastic composite yarn is a composite fiber with high elasticity and is widely used in the textile industry. Before textile work, in order to facilitate the storage and transportation of high-elastic composite yarn, a high-elastic composite yarn winding machine is usually used to wind the high-elastic composite yarn into a specific package form.
[0003] When using existing winding machines, one end of the yarn on the bobbin placed on the positioning seat is passed through the guide hole and wound around the outer surface of the winding drum. The winding drum is driven to rotate, and the yarn is wound on the winding drum under the guidance of the guide hole that moves up and down to complete the winding work.
[0004] The following problems exist: impurities may adhere to the yarn tubes during transportation and placement. If the yarn tubes are placed directly on the positioning seat for winding, the presence of impurities will result in poor quality of the finished product of the high-elastic composite yarn, and will also affect the subsequent processes. Therefore, we propose a winding machine for high-elastic composite yarn. Utility Model Content
[0005] The technical problem to be solved by this utility model is to overcome the existing defects and provide a winding machine for high-elastic composite yarn. The machine uses a cleaning mechanism to clean the high-elastic composite yarn unwound from the bobbin, so that the impurities on the yarn are removed before the winding process, thereby improving the quality of the yarn after winding and reducing the failure of subsequent processes. This can effectively solve the problems in the background art.
[0006] To achieve the above objectives, this utility model provides the following technical solution: a winding machine for high-elastic composite yarn, including a winding frame, the upper surface of which is provided with uniformly distributed winding mechanisms, and also includes a cleanup mechanism;
[0007] The impurity removal mechanism includes a cleaning box, movable plates, brush bristles, sealing rings, yarn inlet holes, discharge ports, and a filter assembly. The front side of the winding frame has a cleaning box corresponding to each winding mechanism. Movable plates are slidably connected to the slots on the front side of the cleaning box. Brush bristles are provided on the inner walls of the clearance holes on the upper surface of the movable plates, and sealing rings are provided on the inner walls of the slots. The inner walls of the sealing rings contact the outer surfaces of adjacent movable plates. Yarn inlet holes and discharge ports are respectively opened on the front and rear sides of the lower surface of the cleaning box. A filter assembly is provided on the upper surface of the winding frame. The impurity removal mechanism cleans the high-elastic composite yarn unwound from the bobbin, removing impurities from the yarn before winding, improving the quality of the wound yarn and reducing defects in subsequent processes.
[0008] Furthermore, it also includes a controller, which is located on the left side of the winding frame. The input terminal of the controller is electrically connected to an external power source to facilitate the normal operation of the equipment.
[0009] Furthermore, the filter assembly includes a filter box and a conveying pipe. The filter box is provided on the upper surface of the winding frame, and the conveying pipe is provided at the feed inlet on the lower rear side of the filter box. The conveying pipe is a converged conveying pipe consisting of a main pipe on the upper side and multiple branch pipes on the lower side. The discharge end of the main pipe is connected to the feed inlet, and the feed ends of the branch pipes are all connected to the adjacent discharge outlets, which facilitates the transfer of impurities from the cleaning box to the filter box.
[0010] Furthermore, the filter assembly also includes slide rails, a filter screen, and a fan. Slide rails are provided on both the left and right walls of the filter box, and a filter screen is slidably connected between the two slide rails. The filter screen is located above the feed inlet. A fan is installed in the mounting hole on the upper surface of the filter box. The input end of the fan is electrically connected to the output end of the controller to facilitate the blocking of impurities.
[0011] Furthermore, the winding mechanism includes rotating rods, ribs, winding cylinders, rib grooves, and a motor. The upper surface of the winding frame is rotatably connected to evenly distributed rotating rods. Each rotating rod has a winding cylinder fitted on its outer surface. Ribs are provided on the outer surface of the rotating rods. Each rib is slidably connected to the inside of a rib groove opened on the inner wall of an adjacent winding cylinder. The inside of the winding frame is equipped with a motor corresponding to each rotating rod. The upper end of the output shaft of the motor is fixedly connected to the lower end of the adjacent rotating rod. The input end of the motor is electrically connected to the output end of the controller to facilitate winding operations.
[0012] Furthermore, it also includes a guiding mechanism, which includes a limiting rod, a movable frame, a support rod, a guide hole, a rotating shaft, a cam, and a second motor. The winding frame has limiting rods on both the left and right sides inside, and a movable frame is slidably connected between the two limiting rods. The front side of the movable frame has a support rod corresponding to the winding cylinder, and the front side of the support rod has a guide hole. The winding frame is rotatably connected to the cam through the rotating shaft inside. The rear side of the winding frame has a second motor. The front end of the output shaft of the second motor is fixedly connected to the rear end of the rotating shaft, and the input end of the second motor is electrically connected to the output end of the controller to facilitate the guidance of the wire.
[0013] Furthermore, the lower end of the front side of the winding frame is provided with two support plates, one above the other. The upper surface of each support plate is provided with evenly distributed positioning seats to facilitate the placement of the yarn tube.
[0014] Compared with the prior art, the beneficial effects of this utility model are as follows: This high-elastic composite yarn winding machine has the following advantages:
[0015] The high-elastic composite yarn unwound from the bobbin enters the cleaning box through the inlet hole and continues to move upwards through the brush bristles. The brush bristles brush off impurities from the yarn and leave them in the cleaning box. At the same time, the fan operates to draw air, along with the impurities, through the discharge port and conveying pipe into the filter box. The impurities entering the filter box are blocked by the filter screen and remain in the filter box, while the air passes through the filter screen and is discharged from the filter box by the fan. This process removes impurities from the yarn before the winding process, improving the quality of the yarn after winding and reducing defects in subsequent processes. Attached Figure Description
[0016] Figure 1 This is a schematic diagram of the structure of this utility model;
[0017] Figure 2 This is an enlarged structural schematic diagram of point A of this utility model;
[0018] Figure 3 This is a cross-sectional structural diagram of the present invention;
[0019] Figure 4 This is an enlarged structural schematic diagram of section B of this utility model;
[0020] Figure 5 This is a schematic diagram of the structure of the cleaning box of this utility model;
[0021] Figure 6 This is a cross-sectional structural diagram of the cleaning box of this utility model.
[0022] In the diagram: 1 Winding frame, 2 Controller, 3 Impurity removal mechanism, 31 Cleaning box, 32 Movable plate, 33 Brush bristles, 34 Sealing ring, 35 Wire inlet hole, 36 Discharge port, 37 Filter assembly, 371 Filter box, 372 Conveying pipe, 373 Slide rail, 374 Filter screen, 375 Fan, 4 Winding mechanism, 41 Rotating rod, 42 Rib, 43 Winding cylinder, 44 Rib groove, 45 Motor I, 5 Guide mechanism, 51 Limiting rod, 52 Movable frame, 53 Support rod, 54 Wire guide hole, 55 Rotating shaft, 56 Cam, 57 Motor II, 6 Support plate, 7 Positioning seat. Detailed Implementation
[0023] 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.
[0024] Please see Figure 1-6This embodiment provides a technical solution: a winding machine for high-elastic composite yarn, including a winding frame 1, with uniformly distributed winding mechanisms 4 on the upper surface of the winding frame 1, a cleaning mechanism 3, and a controller 2. The controller 2 is located on the left side of the winding frame 1, and its input terminal is electrically connected to an external power source. The winding mechanism 4 includes a rotating rod 41, ribs 42, winding cylinders 43, rib grooves 44, and a motor 45. The upper surface of the winding frame 1 is rotatably connected to uniformly distributed rotating rods 41. The outer surface of each rotating rod 41 is fitted with a winding cylinder 43, and the outer surface of the rotating rod 41 is provided with ribs 42. Each rib 42 is slidably connected to the interior of a rib groove 44 opened on the inner wall of an adjacent winding cylinder 43. The interior of the winding frame 1 is provided with a rib groove 44 corresponding to the rotating rod 41. The corresponding motor 45 has its output shaft fixedly connected to the lower end of the adjacent rotating rod 41. The input end of the motor 45 is electrically connected to the output end of the controller 2. It also includes a guide mechanism 5, which comprises a limit rod 51, a movable frame 52, a support rod 53, a wire guide hole 54, a rotating shaft 55, a cam 56, and a second motor 57. Limit rods 51 are provided on both the left and right sides of the winding frame 1. A movable frame 52 is slidably connected between the two limit rods 51. The front side of the movable frame 52 has a support rod 53 corresponding to the winding cylinder 43. A wire guide hole 54 is opened on the front side of each support rod 53. A cam 56 is rotatably connected inside the winding frame 1 via a rotating shaft 55. A second motor 57 is provided on the rear side of the winding frame 1. The front end of the output shaft of motor 7 is fixedly connected to the rear end of the rotating shaft 55. The input end of motor 2 57 is electrically connected to the output end of controller 2. The lower end of the front side of the winding frame 1 is provided with two support plates 6. The upper surface of each support plate 6 is provided with evenly distributed positioning seats 7. The operator places the bobbin on the positioning seats 7 on the support plate 6, and then passes the end of the high-elastic composite yarn on the bobbin through the inlet hole on the vertically corresponding cleaning box 31. The yarn passes through the bristles 33 and then passes through the guide hole 54 and wraps around the outer surface of the winding drum 43 several times to fix it. Through the control of controller 2, the output shaft of motor 1 45 drives the rotating rod 41 to rotate. Under the restriction of ribs 42 and rib grooves 44, the rotating rod 41 drives the winding drum 43 to rotate, so that the yarn is wound around the winding frame. The outer surface of the yarn bobbin 43 is used for winding. At the same time, the motor 57 drives the rotating shaft 55 to rotate. The rotation of the rotating shaft 55 drives the cam 55 to rotate. Under the action of gravity, the lower surface of the movable frame 52 is always in contact with the outer surface of the cam 55. Under the restriction of the limit rod 51, the rotation of the cam 55 drives the movable frame 52 to move up and down reciprocally. Through the support rod 53, the guide hole 54 moves up and down reciprocally. The movement of the guide hole 54 guides the yarn, so that the high-elastic composite yarn can be wound smoothly. When the winding bobbin 43 finishes winding, it can be pulled out along the rib 42 and replaced with a new winding bobbin 43. When the high-elastic composite yarn on the bobbin is used up, it can be removed from the positioning seat 7 and replaced. Then the above steps can be repeated to continue the winding work.
[0025] The impurity removal mechanism 3 includes a cleaning box 31, a movable plate 32, bristles 33, a sealing ring 34, a wire inlet 35, a discharge port 36, and a filter assembly 37. The front side of the winding frame 1 is equipped with a cleaning box 31 corresponding to the winding mechanism 4 (the side of the cleaning box 31 has an air inlet for air circulation). Movable plates 32 are slidably connected to slots on the front side of the cleaning box 31. (The cleaning box 31 and the movable plate 32 are fixed together by fixing bolts. The fixing bolts are threaded into threaded holes on the right side of the cleaning box 31, and are fixed by pressing against the right side of the movable plate 32. When the movable plate 32 needs to be replaced, loosen the fixing bolts to pull out the movable plate 32, and tighten the fixing bolts after replacement). The upper surface of the movable plate 32 is... The inner walls of the clearance holes are all provided with bristles 33, and the inner walls of the slots are all provided with sealing rings 34. The inner walls of the sealing rings 34 are in contact with the outer surfaces of the adjacent movable plates 32. The lower surface of the cleaning box 31 has wire inlet holes 35 and discharge ports 36 on the front and rear sides, respectively. The upper surface of the winding frame 1 is provided with a filter assembly 37, which includes a filter box 371 and a conveying pipe 372. The upper surface of the winding frame 1 is provided with a filter box 371, and the lower rear side of the filter box 371 has a conveying pipe 372. The conveying pipe 372 is a converged conveying pipe with one main pipe on the upper side and multiple branch pipes on the lower side. The discharge end of the main pipe is connected to the inlet, and the inlet ends of the branch pipes are all connected to the adjacent discharge ports 36. The filter assembly 37 also includes The filter box 371 includes slide rails 373, filter screen 374, and fan 375. Slide rails 373 are provided on both the left and right walls of the filter box 371. A filter screen 374 is slidably connected between the two slide rails 373. (A protective door is hinged to the front side of the filter box 371. A sealing strip is provided on the rear side of the protective door to ensure its sealing when closed. The rear side of the filter box 371 contacts the front side of the filter screen 374 when closed. A door lock is provided at the junction of the filter boxes 371, using a common door lock connection method for protective doors in the prior art.) The filter screen 374 is located above the feed inlet. A fan 375 is installed in the mounting hole on the upper surface of the filter box 371. The input end of the fan 375 is electrically connected to the output end of the controller 2. The wire passes through the wire inlet hole 35. After entering the cleaning box 31, the material continues to move upwards, passing through the bristles 33. The bristles 33 brush off impurities from the filaments and leave them inside the cleaning box 31. The sealing ring 34 seals the connection between the cleaning box 31 and the movable plate 32. Simultaneously, the fan 375 operates, drawing air along with the impurities through the discharge port and conveying pipe 372 into the filter box 371. Impurities entering the filter box 371 are trapped inside by the filter screen 374, while the air passes through the filter screen 374 and is discharged from the filter box 371 by the fan 375. After a period of use, the protective door on the front of the filter box 371 can be opened to clean the impurities, or the filter screen 374 can be pulled out along the slide rail 373 for cleaning. After the bristles 33 have been used for a period of time...Loosen the fixing bolts and pull the movable plate 32, along with the brush bristles 33, out of the cleaning box 31 for replacement. After replacement, tighten the fixing bolts to secure the movable plate 32 inside the cleaning box 31.
[0026] The working principle of the high-elastic composite yarn winding machine provided by this utility model is as follows: The operator places the bobbin of yarn on the positioning seat 7 on the support plate 6, and then passes the end of the high-elastic composite yarn on the bobbin through the inlet hole on the vertically corresponding cleaning box 31. The yarn comes out from the brush 33, and then passes the yarn through the guide hole 54 and wraps it around the outer surface of the winding drum 43 several times to fix it. Through the control of the controller 2, the output shaft of the motor 45 drives the rotating rod 41 to rotate. Under the restriction of the ribs 42 and the rib grooves 44, the rotating rod 41 drives the winding drum 43 to rotate, so that the yarn is wound around the... The winding spool 43 performs winding operations on its outer surface. Simultaneously, motor 57 drives shaft 55 to rotate, which in turn drives cam 55. Under gravity, the lower surface of the movable frame 52 remains in contact with the outer surface of the cam 55. Limited by the limit rod 51, the rotation of the cam 55 causes the movable frame 52 to move up and down reciprocally. This movement, via support rod 53, drives the guide hole 54 to move up and down reciprocally. The movement of the guide hole 54 guides the yarn, allowing the high-elastic composite yarn to complete the winding operation smoothly. After entering the cleaning box 31 through the inlet hole 35, the yarn continues to... The brush moves upward through the bristles 33, which brush off impurities from the filaments and leave them in the cleaning box 31. The sealing ring 34 seals the connection between the cleaning box 31 and the movable plate 32. Simultaneously, the fan 375 draws air, along with impurities, through the discharge port and conveying pipe 372 into the filter box 371. Impurities entering the filter box 371 are trapped by the filter screen 374, while air passes through the filter screen 374 and is discharged from the filter box 371 by the fan 375. After a period of use, the filter box 371 can be cleaned. The front protective door can be opened to clean impurities. Alternatively, the filter screen 374 can be pulled out along the slide rail 373 for cleaning. After the brush bristles 33 have been used for a period of time, loosen the fixing bolts and pull the movable plate 32 along with the brush bristles 33 out of the cleaning box 31 for replacement. After replacement, tighten the fixing bolts to fix the movable plate 32 in the cleaning box 31. After the winding bobbin 43 has finished winding, pull it out along the rib 42 to replace it with a new winding bobbin 43. When the high-elastic composite yarn on the bobbin is used up, remove it from the positioning seat 7 for replacement. Then repeat the above steps to continue winding.
[0027] It is worth noting that the controller 2 disclosed in the above embodiments can be an STC89C52, the fan 375 can be an SF axial flow fan, and the motor 45 and motor 57 can be YP-100 series. The controller 2 controls the operation of the fan 375, motor 45 and motor 57 using methods commonly used in the prior art.
[0028] The above description is merely an embodiment of this utility model and does not limit the patent scope of this utility model. Any equivalent structural or procedural transformations made based on the content of this utility model specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this utility model.
Claims
1. A winding machine for high-elastic composite yarn, comprising a winding frame (1), wherein the upper surface of the winding frame (1) is provided with uniformly distributed winding mechanisms (4), characterized in that: It also includes a cleaning mechanism (3); The impurity removal mechanism (3) includes a cleaning box (31), a movable plate (32), bristles (33), a sealing ring (34), a wire inlet (35), a discharge port (36), and a filter assembly (37). The front side of the winding frame (1) is provided with a cleaning box (31) corresponding to the winding mechanism (4). The slots on the front side of the cleaning box (31) are slidably connected to the movable plate (32). The inner walls of the clearance holes on the upper surface of the movable plate (32) are provided with bristles (33). The inner walls of the slots are provided with sealing rings (34). The inner walls of the sealing rings (34) are in contact with the outer surfaces of the adjacent movable plates (32). The front and rear sides of the lower surface of the cleaning box (31) are respectively provided with a wire inlet (35) and a discharge port (36). The upper surface of the winding frame (1) is provided with a filter assembly (37).
2. The winding machine for high-elastic composite yarn according to claim 1, characterized in that: It also includes a controller (2), which is located on the left side of the winding frame (1), and the input end of the controller (2) is electrically connected to an external power source.
3. A winding machine for high-elastic composite yarn according to claim 2, characterized in that: The filter assembly (37) includes a filter box (371) and a conveying pipe (372). The filter box (371) is provided on the upper surface of the winding frame (1). The conveying pipe (372) is provided at the feed inlet on the lower side of the rear side of the filter box (371). The conveying pipe (372) is a converged conveying pipe consisting of a main pipe on the upper side and multiple branch pipes on the lower side. The discharge end of the main pipe is connected to the feed inlet, and the feed ends of the branch pipes are all connected to the adjacent discharge outlet (36).
4. A winding machine for high-elastic composite yarn according to claim 3, characterized in that: The filter assembly (37) also includes a slide rail (373), a filter screen (374) and a fan (375). The left and right walls of the filter box (371) are provided with slide rails (373). A filter screen (374) is slidably connected between the two slide rails (373). The filter screen (374) is located above the feed inlet. A fan (375) is provided in the mounting hole on the upper surface of the filter box (371). The input end of the fan (375) is electrically connected to the output end of the controller (2).
5. A winding machine for high-elastic composite yarn according to claim 2, characterized in that: The winding mechanism (4) includes a rotating rod (41), ribs (42), winding cylinders (43), rib grooves (44), and a motor (45). The upper surface of the winding frame (1) is rotatably connected with evenly distributed rotating rods (41). The outer surface of the rotating rods (41) is fitted with winding cylinders (43). The outer surface of the rotating rods (41) is provided with ribs (42). The ribs (42) are slidably connected to the inside of the rib grooves (44) opened on the inner wall of the adjacent winding cylinders (43). The inside of the winding frame (1) is provided with a motor (45) corresponding to the rotating rods (41). The upper end of the output shaft of the motor (45) is fixedly connected to the lower end of the adjacent rotating rods (41). The input end of the motor (45) is electrically connected to the output end of the controller (2).
6. A winding machine for high-elastic composite yarn according to claim 5, characterized in that: It also includes a guide mechanism (5), which includes a limiting rod (51), a movable frame (52), a support rod (53), a wire guide hole (54), a rotating shaft (55), a cam (56), and a second motor (57). The winding frame (1) is provided with limiting rods (51) on both the left and right sides. A movable frame (52) is slidably connected between the two limiting rods (51). The front side of the movable frame (52) is provided with a support rod (53) corresponding to the winding cylinder (43). The front side of the support rod (53) is provided with a wire guide hole (54). The inside of the winding frame (1) is rotatably connected to the cam (56) through the rotating shaft (55). The rear side of the winding frame (1) is provided with a second motor (57). The front end of the output shaft of the second motor (57) is fixedly connected to the rear end of the rotating shaft (55). The input end of the second motor (57) is electrically connected to the output end of the controller (2).
7. A winding machine for high-elastic composite yarn according to claim 1, characterized in that: The lower front side of the winding frame (1) is provided with two support plates (6), and the upper surface of each support plate (6) is provided with evenly distributed positioning seats (7).