Automatic oiling device for ultra-high speed spinning

By installing an oil drain pipe and gear system in the automatic oiling device for spinning, the problem of oil dripping is solved, and effective oil collection and efficient oiling are achieved.

CN224450950UActive Publication Date: 2026-07-03WUXI LIYANG FIBRE CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
WUXI LIYANG FIBRE CO LTD
Filing Date
2025-06-25
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing automatic oiling devices often leave excess oil residue on the extrusion structure after oiling during spinning, causing oil to drip onto other equipment and affecting environmental hygiene.

Method used

An automatic oiling device for ultra-high-speed spinning was designed. By setting an oil drain pipe at the bottom of the oil squeezing sleeve, excess oil is squeezed out from the spinning process and discharged into the oil receiving annular groove through the oil drain pipe to prevent oil dripping. The drive motor drives the gear system to rotate the oil squeezing sleeve, thereby improving the oil squeezing effect. The position of the oil squeezing sleeve can be adjusted by adjusting the slider and the motor, which facilitates the installation and cleaning of the oil receiving annular groove.

Benefits of technology

It effectively collects and drains excess oil, prevents oil dripping, improves environmental hygiene, and enhances the efficiency and effectiveness of oiling in spinning.

✦ Generated by Eureka AI based on patent content.

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    Figure CN224450950U_ABST
Patent Text Reader

Abstract

This utility model relates to an automatic oiling device for ultra-high-speed spinning, belonging to the field of spinning oiling technology. It includes a winding machine, a positioning ring fixedly installed on the top of the winding machine, an oil-receiving annular groove placed on the top of the winding machine, a support plate fixedly installed on one side of the winding machine, and an oil-squeezing assembly slidably installed on one side of the support plate. The oil-squeezing assembly includes a sliding mounting plate slidably installed on one side of the support plate. This automatic oiling device for ultra-high-speed spinning uses an oil drain pipe at the bottom of the oil-squeezing sleeve. As the spinning yarn passes through the oil-squeezing sleeve, excess oil is squeezed out from the spinning yarn and discharged through the oil drain pipe. An oil-receiving annular groove is provided at the top of the winding machine to collect the discharged oil, preventing oil dripping. This solves the problem in common automatic oiling devices where oil residue remains on the oil-squeezing structure after squeezing out excess oil from the spinning yarn, leading to leakage and environmental hygiene issues.
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Description

Technical Field

[0001] This utility model relates to the field of spinning oiling technology, specifically to an automatic oiling device for ultra-high-speed spinning. Background Technology

[0002] Spinning oiling is an important step in the production of chemical fibers. It involves applying or impregnating specific oils onto the fibers during spinning or post-processing. This process improves various fiber properties to meet the requirements of subsequent processing and use. Specifically, it reduces static electricity buildup during processing, enhances fiber cohesion, bundle strength, and flexibility, reduces friction between fibers and between fibers and metal equipment, prevents fiber breakage and wear, and also provides lubrication, rust prevention, and mildew prevention, thereby improving fiber processability and product quality.

[0003] An automatic oiling device is needed in the spinning oiling process. Utility model patent CN222008190U discloses an ultra-high-speed spinning automatic oiling device, relating to the field of spinning oiling technology. This utility model includes a winding machine, a main oiling tube, a sleeve, and a single-spindle oiling tube. Three cylinders are fixedly connected to the top of the winding machine along its transverse centerline. Each cylinder has a wire outlet tube extending through its top. A fixed outer shell is fixed to the top of the wire outlet tube, and a rubber disc is fixed inside the fixed outer shell. Both the rubber disc and the fixed outer shell have wire-passing holes extending through their axial centerlines. Three uprights are fixed to the top of the winding machine, and sleeves are fixed to the top of each upright. Sleeve holes are extending through the lower part of the sleeve's periphery, and single-spindle oiling tubes are movably connected through these sleeve holes. The main oiling tube is located above the winding machine. This invention solves the problem that after oiling, spinning is prone to severe oil spillage at high speeds and it is difficult to adjust the oil delivery rate to balance the oil consumption rate of spinning by setting up a winding machine, a main oiling pipe, a sleeve, and a single-spindle oiling pipe.

[0004] However, after the automatic oiling device squeezes out the excess oil from the spinning process, the oil remains on the oiling structure and is prone to leakage, causing the oil to drip onto other equipment and affecting environmental hygiene. Therefore, an ultra-high-speed spinning automatic oiling device is proposed to solve the problems mentioned above. Utility Model Content

[0005] To address the shortcomings of existing technologies, this utility model provides an automatic oiling device for ultra-high-speed spinning, which has the advantages of collecting the extruded oil and preventing oil leakage. It solves the problem that in common automatic oiling devices, after extruding excess oil from spinning, oil remains on the extrusion structure, and oil is prone to leakage, causing oil to drip onto other equipment and affecting environmental hygiene.

[0006] To achieve the above objectives, this utility model provides the following technical solution: an automatic oiling device for ultra-high speed spinning, comprising a winding machine, a positioning ring fixedly installed on the top of the winding machine, an oil receiving annular groove placed on the top of the winding machine, a support plate fixedly installed on one side of the winding machine, and an oil squeezing assembly slidably installed on one side of the support plate.

[0007] The oil squeezing assembly includes a sliding mounting plate slidably mounted on one side of the support plate, an oil squeezing sleeve rotatably mounted on the top of the sliding mounting plate, and an oil discharge pipe fixedly mounted on the bottom of the oil squeezing sleeve.

[0008] By adopting the above technical solution, the winding machine winds up the spinning yarn, and the spinning yarn passes through the oil squeezing sleeve to squeeze out the excess oil on the spinning yarn. An oil drain pipe is set at the bottom of the oil squeezing sleeve to discharge the excess oil squeezed out from the spinning yarn. An oil receiving annular groove is set at the top of the winding machine to collect the discharged oil in the oil receiving annular groove to prevent the oil from dripping outside.

[0009] Furthermore, the top of the oil squeezing sleeve is provided with a compression groove, and the bottom of the oil squeezing sleeve is provided with a through hole. The inner diameter of the compression groove gradually decreases from top to bottom, and the compression groove is connected to the through hole.

[0010] The beneficial effect of adopting the above-mentioned further scheme is that the spinning yarn passes through the compression groove and the through hole in sequence, and the excess oil on the spinning yarn is squeezed out in the gradually narrowing inner diameter of the compression groove.

[0011] Furthermore, the oil drain pipe is connected to the compression tank, and the bottom end of the oil drain pipe is aligned with the oil receiving annular groove.

[0012] The beneficial effect of adopting the above-mentioned further solution is that after the oil is squeezed out, it remains in the compression tank and is discharged into the oil receiving annular tank through the oil discharge pipe.

[0013] Furthermore, a driven gear is fixedly installed on the surface of the oil squeezing sleeve, and a driving gear is rotatably installed on the top of the sliding mounting plate, with the driven gear and the driving gear meshing together.

[0014] The beneficial effect of adopting the above-mentioned further solution is that the rotation of the driving gear drives the rotation of the driven gear, which in turn drives the oil squeezing sleeve to rotate, thereby improving the oil squeezing effect.

[0015] Furthermore, a drive motor is fixedly mounted on the bottom of the sliding mounting plate, and the output shaft of the drive motor is fixedly connected to the bottom of the drive gear.

[0016] The beneficial effect of adopting the above-mentioned further solution is that the drive motor drives the active gear to rotate, providing power for the rotation of the oil squeezing sleeve.

[0017] Furthermore, an adjusting slider is fixedly installed on one side of the sliding mounting plate, and two mounting side plates are fixedly installed on one side of the supporting upright plate, with the adjusting slider located between the two mounting side plates.

[0018] The beneficial effect of adopting the above-mentioned further solution is that: by adjusting the slider to move between the two mounting side plates and adjusting the position of the sliding mounting plate, the sliding mounting plate moves upward when the oil receiving annular groove is placed and removed, so that the oil squeezing sleeve separates from the oil receiving annular groove.

[0019] Furthermore, an adjusting screw is rotatably mounted between the two mounting side plates, and the adjusting screw is threadedly connected to the adjusting slider. An adjusting motor is fixedly mounted at the bottom of the lower mounting side plate, and the output shaft of the adjusting motor is fixedly connected to the bottom end of the adjusting screw.

[0020] The beneficial effect of adopting the above-mentioned further solution is that the adjusting motor drives the adjusting screw to rotate, which in turn drives the adjusting slider to move up and down, and drives the oil squeezing sleeve to move up and down.

[0021] Furthermore, a mounting horizontal plate is fixedly installed on one side of the supporting vertical plate, an oil-immersing funnel is fixedly installed on the top of the mounting horizontal plate, and a reinforcing rib is fixedly installed on one side of the supporting vertical plate, with the bottom of the reinforcing rib fixedly connected to the top of the mounting horizontal plate.

[0022] The beneficial effect of adopting the above-mentioned further scheme is that the spinning yarn passes through the oil immersion funnel, oil is added to the oil immersion funnel, and the spinning yarn comes into contact with the oil in the oil immersion funnel for rapid oiling.

[0023] Compared with the prior art, this utility model provides an automatic oiling device for ultra-high speed spinning, which has the following beneficial effects:

[0024] 1. This ultra-high-speed automatic oiling device for spinning uses an oil drain pipe at the bottom of the oil squeezing sleeve. As the spinning yarn passes through the oil squeezing sleeve, excess oil on the spinning yarn is squeezed out and discharged from the oil drain pipe. An oil receiving annular groove is set at the top of the winding machine to collect the discharged oil and prevent it from dripping outside. This solves the problem of common automatic oiling devices leaving oil residue on the oil squeezing structure after squeezing out excess oil from the spinning yarn, which easily leaks out and drips onto other equipment, affecting environmental hygiene.

[0025] 2. This ultra-high-speed spinning automatic oiling device drives the drive motor to rotate the active gear, which in turn drives the driven gear to rotate, which in turn drives the oil squeezing sleeve to rotate. This causes the oil squeezing sleeve to rotate on the spinning surface, improving the oil squeezing effect and preventing excessive oil from being thrown off the spinning process in subsequent processing. Attached Figure Description

[0026] Figure 1This is a front sectional view of the structure of this utility model;

[0027] Figure 2 This is a front view of the structure of this utility model;

[0028] Figure 3 This is a front sectional view of the oil extrusion sleeve of this utility model;

[0029] Figure 4 This is a three-dimensional view of the oil extrusion sleeve of this utility model.

[0030] In the diagram: 1. Winding machine; 2. Positioning ring; 3. Oil receiving annular groove; 4. Support plate; 5. Sliding mounting plate; 6. Oil squeezing sleeve; 61. Compression groove; 62. Through hole; 7. Oil drain pipe; 8. Driven gear; 9. Drive gear; 10. Drive motor; 11. Adjusting slider; 12. Mounting side plate; 13. Adjusting screw; 14. Adjusting motor; 15. Mounting horizontal plate; 16. Oil immersion funnel; 17. Reinforcing rib plate. Detailed Implementation

[0031] Please see Figures 1 to 4 This embodiment of an automatic oiling device for ultra-high-speed spinning includes a winding machine 1, a positioning ring 2 fixedly installed on the top of the winding machine 1, an oil-receiving annular groove 3 placed on the top of the winding machine 1, a support plate 4 fixedly installed on one side of the winding machine 1, and an oil-squeezing assembly slidably installed on one side of the support plate 4. The positioning ring 2 limits the oil-receiving annular groove 3 to the center of the top of the winding machine 1, aligning it with the oil-squeezing assembly.

[0032] Specifically, the oil extrusion assembly includes a sliding mounting plate 5 slidably mounted on one side of the support plate 4, an oil extrusion sleeve 6 rotatably mounted on the top of the sliding mounting plate 5, and an oil discharge pipe 7 fixedly mounted on the bottom of the oil extrusion sleeve 6. The filaments pass sequentially through the oil extrusion sleeve 6 and the oil receiving annular groove 3 into the winding machine 1 for winding. The inner wall of the oil receiving annular groove 3 is lower than its outer wall. When the oil extrusion sleeve 6 extends into the oil receiving annular groove 3, the bottom of the oil extrusion sleeve 6 is lower than the outer wall of the oil receiving annular groove 3, and the bottom of the oil extrusion sleeve 6 does not contact the interior of the oil receiving annular groove 3.

[0033] The winding machine 1 winds up the spinning yarn, which passes through the oil squeezing sleeve 6 to squeeze out excess oil from the spinning yarn. An oil drain pipe 7 is set at the bottom of the oil squeezing sleeve 6 to discharge the excess oil squeezed out from the spinning yarn. An oil receiving annular groove 3 is set at the top of the winding machine 1 to collect the discharged oil in the oil receiving annular groove 3 to prevent the oil from dripping outside.

[0034] It should be noted that the winding machine 1 is a device used in the textile industry to wind materials such as spun yarn and fiber into a specific shape package. It includes a winding mechanism to realize the winding of the yarn, a tension control system to ensure the quality of the package, a yarn guiding mechanism to accurately guide the yarn to the winding position, and a length measuring device to measure the length of the yarn. In addition, in order to improve production efficiency, some winding machines 1 are also equipped with automated feeding and bobbin changing devices.

[0035] The winding mechanism includes a winding drum and a transmission device. The winding drum supports the package and drives it to rotate, while the transmission device provides power to the winding drum, enabling it to rotate at a set speed and direction, thereby achieving yarn winding. The transmission device generally consists of a motor, reducer, gears, etc., and its speed can be adjusted according to different winding speed requirements.

[0036] Secondly, the yarn guiding mechanism includes yarn guide hooks, yarn guide rods, and yarn guide wheels. In a reciprocating yarn guiding mechanism, the yarn guide rods reciprocate, causing the yarn to be evenly distributed back and forth on the surface of the package. In a rotary yarn guiding mechanism, the yarn guide wheels rotate synchronously with the rotation of the package, guiding the yarn to be evenly wound on the package.

[0037] Please see Figure 3 and Figure 4 In this embodiment, the top of the oil squeezing sleeve 6 is provided with a compression groove 61, and the bottom of the oil squeezing sleeve 6 is provided with a through hole 62. The inner diameter of the compression groove 61 gradually decreases from top to bottom, and the compression groove 61 is connected to the through hole 62. The spinning yarn enters the oil squeezing sleeve 6 from the compression groove 61 and exits from the through hole 62. In the gradually decreasing inner diameter of the compression groove 61, excess oil in the spinning yarn is squeezed out.

[0038] Please see Figure 1 and Figure 2 In this embodiment, the oil drain pipe 7 is connected to the compression tank 61, and the bottom end of the oil drain pipe 7 is aligned with the oil receiving annular groove 3. After excess oil is squeezed out during spinning, it is discharged through the oil drain pipe 7 and flows into the oil receiving annular groove 3 for collection, which facilitates the recovery or cleaning of excess oil.

[0039] The driven gear 8 is fixedly mounted on the surface of the oil squeezing sleeve 6, and the driving gear 9 is rotatably mounted on the top of the sliding mounting plate 5. The driven gear 8 and the driving gear 9 mesh with each other. When the driving gear 9 rotates, it drives the driven gear 8 to rotate, which in turn drives the oil squeezing sleeve 6 to rotate, thereby increasing the oil squeezing effect during oil squeezing.

[0040] Secondly, a drive motor 10 is fixedly mounted on the bottom of the sliding mounting plate 5, and the output shaft of the drive motor 10 is fixedly connected to the bottom of the drive gear 9. The drive motor 10 drives the drive gear 9 to rotate, thereby driving the oil squeezing sleeve 6 to rotate.

[0041] Meanwhile, an adjusting slider 11 is fixedly installed on one side of the sliding mounting plate 5, and two mounting side plates 12 are fixedly installed on one side of the supporting upright plate 4. The adjusting slider 11 is located between the two mounting side plates 12. By adjusting the slider 11, the sliding mounting plate 5 is moved up and down, causing the oil squeezing sleeve 6 to approach and move away from the oil receiving annular groove 3. When installing the oil receiving annular groove 3, the oil squeezing sleeve 6 rises, making it easier to place the oil receiving annular groove 3 on the top of the winding machine 1. After installation, the oil squeezing sleeve 6 moves down, and its bottom extends into the oil receiving annular groove 3.

[0042] An adjusting screw 13 is rotatably mounted between the two mounting side plates 12. The adjusting screw 13 is threadedly connected to the adjusting slider 11. An adjusting motor 14 is fixedly mounted at the bottom of the lower mounting side plate 12. The output shaft of the adjusting motor 14 is fixedly connected to the bottom end of the adjusting screw 13. The adjusting motor 14 drives the adjusting screw 13 to rotate, which in turn drives the adjusting slider 11 to move up and down, and thus drives the sliding mounting plate 5 to move up and down.

[0043] When too much oil is collected in the oil collecting annular groove 3, the adjusting motor 14 drives the adjusting screw 13 to rotate, which in turn drives the adjusting slider 11 to rise, which in turn drives the sliding mounting plate 5 to rise, so that the oil squeezing sleeve 6 moves upward to the top of the oil collecting annular groove 3. Then the oil collecting annular groove 3 is removed from the positioning ring 2, which makes it convenient to recover or clean the oil in the oil collecting annular groove 3.

[0044] Secondly, a mounting plate 15 is fixedly installed on one side of the supporting upright plate 4, and an oil-immersing funnel 16 is fixedly installed on the top of the mounting plate 15. A reinforcing rib 17 is fixedly installed on one side of the supporting upright plate 4, and the bottom of the reinforcing rib 17 is fixedly connected to the top of the mounting plate 15. Oil is added to the oil-immersing funnel 16, and the spinning yarn passes through the oil-immersing funnel 16, coming into contact with the oil in the oil-immersing funnel 16, so that the oil is immersed in the spinning yarn, thus oiling the spinning yarn. The spinning yarn passes through the oil-immersing funnel 16, the oil-extrusion sleeve 6, and the oil-receiving annular groove 3 from top to bottom, and finally enters the winding machine 1.

[0045] In use, oil is added to the oil immersion funnel 16, and the spinning yarn passes through the oil immersion funnel 16, coming into contact with the oil in the oil immersion funnel 16, so that the oil is immersed in the spinning yarn, oiling the spinning yarn. The spinning yarn passes through the oil squeezing sleeve 6, and in the gradually narrowing inner diameter of the compression groove 61, the excess oil in the spinning yarn is squeezed out and discharged through the oil discharge pipe 7, flowing into the oil receiving annular groove 3 for collection, which is convenient for recycling or cleaning of excess oil. At the same time, the drive motor 10 drives the drive gear 9 to rotate, which drives the driven gear 8 to rotate, thereby driving the oil squeezing sleeve 6 to rotate, improving the oil squeezing effect.

[0046] The working principle of the above embodiment is as follows: the spinning thread passes through the oil squeezing sleeve 6, squeezes out the excess oil on the spinning thread and leaves it in the compression tank 61. An oil drain pipe 7 is set at the bottom of the oil squeezing sleeve 6, so that the excess oil squeezed out from the spinning thread is discharged from the bottom of the compression tank 61 through the oil drain pipe 7 into the oil receiving annular groove 3 to prevent the oil from dripping outside.

Claims

1. An automatic super high speed spinning oiling device, characterized in that, Includes a winding machine (1), a positioning ring (2) fixedly installed on the top of the winding machine (1), an oil receiving annular groove (3) placed on the top of the winding machine (1), a support plate (4) fixedly installed on one side of the winding machine (1), and an oil squeezing assembly slidably installed on one side of the support plate (4). The oil squeezing assembly includes a sliding mounting plate (5) slidably mounted on one side of the support plate (4), an oil squeezing sleeve (6) rotatably mounted on the top of the sliding mounting plate (5), and an oil discharge pipe (7) fixedly mounted on the bottom of the oil squeezing sleeve (6).

2. The automatic oiling device for ultra-high-speed spinning according to claim 1, characterized in that: The top of the oil squeezing sleeve (6) is provided with a compression groove (61), and the bottom of the oil squeezing sleeve (6) is provided with a through hole (62). The inner diameter of the compression groove (61) gradually decreases from top to bottom, and the compression groove (61) is connected to the through hole (62).

3. The automatic super high speed spinning oiling device according to claim 2, characterized in that: The oil drain pipe (7) is connected to the compression tank (61), and the bottom end of the oil drain pipe (7) is aligned with the oil receiving annular groove (3).

4. The automatic oiling device for ultra-high-speed spinning according to claim 1, characterized in that: The surface of the oil squeezing sleeve (6) is fixedly mounted with a driven gear (8), and the top of the sliding mounting plate (5) is rotatably mounted with a driving gear (9). The driven gear (8) and the driving gear (9) mesh with each other.

5. The automatic super high speed spinning oiling device according to claim 4, characterized in that: A drive motor (10) is fixedly mounted on the bottom of the sliding mounting plate (5), and the output shaft of the drive motor (10) is fixedly connected to the bottom of the drive gear (9).

6. The automatic super high speed spinning oiling device according to claim 1, characterized in that: An adjusting slider (11) is fixedly installed on one side of the sliding mounting plate (5), and two mounting side plates (12) are fixedly installed on one side of the supporting plate (4). The adjusting slider (11) is located between the two mounting side plates (12).

7. The automatic super high speed spinning oiling device according to claim 6, characterized in that: An adjusting screw (13) is rotatably mounted between the two mounting side plates (12). The adjusting screw (13) is threadedly connected to the adjusting slider (11). An adjusting motor (14) is fixedly mounted at the bottom of the lower mounting side plate (12). The output shaft of the adjusting motor (14) is fixedly connected to the bottom end of the adjusting screw (13).

8. The automatic super high speed spinning oiling device according to claim 1, characterized in that: A mounting plate (15) is fixedly installed on one side of the support plate (4), an oil-immersing funnel (16) is fixedly installed on the top of the mounting plate (15), a reinforcing rib plate (17) is fixedly installed on one side of the support plate (4), and the bottom of the reinforcing rib plate (17) is fixedly connected to the top of the mounting plate (15).