Conical textile bobbin

By introducing an upper reinforcing ring, a lower reinforcing ring, and a reinforcing rib structure into the tapered textile tube, combined with a composite coating and tensioning components, the problems of easy deformation of the tube and loose yarn are solved, thereby improving structural strength and yarn winding tightness, and eliminating static electricity accumulation.

CN224467266UActive Publication Date: 2026-07-07盐城市明磊纺织器材有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
盐城市明磊纺织器材有限公司
Filing Date
2025-07-15
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Traditional conical textile tube structures lack strength, are prone to deformation, and are not easy to tighten yarns; high-elasticity yarns are also prone to loosening.

Method used

The strength of the tube body is enhanced by adopting an upper reinforcing ring, a lower reinforcing ring and a reinforcing rib structure. Combined with a composite coating group, the yarn friction is increased. The yarn is tightened by a tensioning component and dissipated through a spiral heat dissipation channel and heat dissipation holes.

Benefits of technology

It improves the structural strength of the tube body, prevents deformation, enhances the tightness of yarn winding, avoids static electricity accumulation, and extends service life.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to textile pipe winding technology field, and disclose a kind of conical textile pipe winding, including pipe winding body, the bottom surface of pipe winding body is fixedly arranged with lower reinforcing ring, the top surface of pipe winding body is fixedly arranged with upper reinforcing ring, the inner wall of pipe winding body is equipped with cavity, the inside of cavity is fixedly arranged with reinforcing rib, the surface of pipe winding body is fixedly arranged with antiskid layer, the surface of antiskid layer is coated with composite coating group, the surface of pipe winding body is equipped with spiral heat dissipation channel, the top of pipe winding body is clamped with top cover, and the inside one side of top cover is fixedly installed with tensioning assembly. The conical textile pipe winding, by the setting of composite coating group, antiskid layer and nanometer ceramic particle coating can increase the friction between yarn and pipe winding body, and it is not easy to slip off when winding yarn, and the winding of yarn is facilitated, ultra-thin carbon nanotube coating can eliminate static electricity, avoid the static electricity accumulation generated by friction when high-speed winding yarn.
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Description

Technical Field

[0001] This utility model relates to the field of textile tube technology, and in particular to a tapered textile tube. Background Technology

[0002] In the textile industry, tapered textile winding tubes are key components for yarn winding and storage, and are widely used in spinning, weaving, dyeing, and other processes. Traditional tapered winding tubes are mostly made of paper, plastic, or composite materials.

[0003] A dustproof self-winding textile roll tube disclosed in announcement number CN207293721U, although the dustproof self-winding textile roll tube described in this utility model is equipped with a locking plate, a dust-absorbing plate and a high-resistance transmission plate, can tightly lock one end of the fabric onto the roll tube to prevent it from loosening during the weaving process, can absorb the dust generated during processing to prevent dust from soiling the fabric, and can prevent sudden increases in rotation speed from tearing the fabric, reducing unnecessary losses, and is suitable for different working conditions, bringing better application prospects.

[0004] However, this dustproof self-winding textile tube has the following disadvantages: it is not easy to improve the structural strength of the tube, long-term winding can easily cause the tube to deform and affect its service life. In addition, it is not easy to tighten the yarn, and some high-elasticity yarns are prone to tangling and loosening. Utility Model Content

[0005] (a) Technical problems to be solved

[0006] The purpose of this utility model is to provide a conical textile tube to solve the problems mentioned in the background art, such as the difficulty in improving the structural strength of the tube, the tendency of long-term winding rotation to cause tube deformation and affect service life, and the difficulty in tightening the yarn, which can easily lead to loose winding of some high-elasticity yarns.

[0007] (II) Technical Solution

[0008] To achieve the above objectives, this utility model provides the following technical solution: a conical textile tube, comprising a tube body, a lower reinforcing ring fixedly disposed on the bottom surface of the tube body, an upper reinforcing ring fixedly disposed on the top surface of the tube body, a cavity formed in the inner wall of the tube body, a reinforcing rib fixedly disposed inside the cavity, an anti-slip layer fixedly disposed on the surface of the tube body, a composite coating group coated on the surface of the anti-slip layer, a spiral heat dissipation channel formed on the surface of the tube body, a top cover snapped onto the top of the tube body, and a tensioning component fixedly installed on one side inside the top cover.

[0009] As a further embodiment of this invention, the composite coating group includes a nano-ceramic particle coating and an ultra-thin carbon nanotube coating. The nano-ceramic particle coating is applied to the surface of the anti-slip layer, and the ultra-thin carbon nanotube coating is applied to the surface of the nano-ceramic particle coating. The composite coating group is used to prevent yarn slippage and eliminate static electricity.

[0010] As a further embodiment of this utility model, the tensioning assembly includes a hydraulic rod and a threading ring. The hydraulic rod is fixedly installed on one side inside the top cover, and the threading ring is fixedly disposed at the output end of the hydraulic rod. The tensioning assembly is used to tension the yarn.

[0011] As a further embodiment of this utility model, the number of spiral heat dissipation channels is several, and the several spiral heat dissipation channels are distributed in a ring array from top to bottom, which facilitates heat dissipation.

[0012] As a further embodiment of this utility model, the number of cavities and reinforcing ribs are four sets, and the four sets of cavities and reinforcing ribs are arranged in a ring array on the inner wall of the rolled tube body. The reinforcing ribs are used to improve the strength of the rolled tube body and prevent deformation.

[0013] As a further embodiment of this utility model, the surfaces of the anti-slip layer and the composite coating group are provided with heat dissipation holes, which are adapted to the spiral heat dissipation channel and facilitate heat dissipation.

[0014] As a further embodiment of this invention, the anti-slip layer is made of polylactic acid modified silicone, which increases the friction of the yarn and makes it less prone to slipping.

[0015] (III) Beneficial Effects

[0016] This utility model provides a tapered textile tube, which has the following beneficial effects:

[0017] 1. This tapered textile roll tube, through the setting of a composite coating group, the anti-slip layer and the nano-ceramic particle coating can increase the friction between the yarn and the roll tube body, making it less likely to slip and detach when winding the yarn, and facilitating the winding of the yarn. The ultra-thin carbon nanotube coating can eliminate static electricity and avoid the accumulation of static electricity caused by friction when winding the yarn at high speed.

[0018] 2. This conical textile tube, through the setting of upper reinforcing rings, lower reinforcing rings and reinforcing ribs, improves the overall structural strength of the tube body, making it less prone to deformation and with a long service life.

[0019] 3. This tapered textile roll tube, through the setting of the tensioning component, allows the yarn to pass through the threading ring. Opening the hydraulic rod drives the threading ring to tighten the yarn, compensating for the yarn elasticity and preventing the yarn from loosening during winding. Attached Figure Description

[0020] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0021] Figure 2 This is a schematic diagram of the tensioning mechanism of this utility model;

[0022] Figure 3 This is a schematic diagram of the upper and lower reinforcing rings of this utility model;

[0023] Figure 4 This is a schematic diagram of the composite coating structure of this utility model;

[0024] Figure 5 This is a schematic diagram of the overall cross-sectional structure of this utility model.

[0025] In the diagram: 1. Tube body; 2. Lower reinforcing ring; 3. Upper reinforcing ring; 4. Reinforcing rib; 5. Anti-slip layer; 6. Composite coating group; 601. Nano-ceramic particle coating; 602. Ultra-thin carbon nanotube coating; 7. Spiral heat dissipation channel; 8. Top cover; 9. Tensioning assembly; 901. Hydraulic rod; 902. Threading ring. Detailed Implementation

[0026] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present utility model without creative effort are within the scope of protection of the present utility model.

[0027] Please see Figures 1 to 5 This utility model provides a technical solution: a conical textile tube, including a tube body 1, a lower reinforcing ring 2 fixedly disposed on the bottom surface of the tube body 1, an upper reinforcing ring 3 fixedly disposed on the top surface of the tube body 1, a cavity opened in the inner wall of the tube body 1, and a reinforcing rib 4 fixedly disposed inside the cavity. Through the arrangement of the upper reinforcing ring 3, the lower reinforcing ring 2 and the reinforcing rib 4, the overall structural strength of the tube body 1 is improved, making it less prone to deformation and with a long service life.

[0028] An anti-slip layer 5 is fixedly provided on the surface of the tube body 1. The surface of the anti-slip layer 5 is coated with a composite coating group 6. Through the setting of the composite coating group 6, the anti-slip layer 5 and the nano-ceramic particle coating 601 can increase the friction between the yarn and the tube body 1, making it less likely to slip and detach when winding the yarn, and facilitating the winding of the yarn. The ultra-thin carbon nanotube coating 602 can eliminate static electricity and prevent static electricity accumulation caused by friction when winding the yarn at high speed.

[0029] The surface of the tube body 1 is provided with a spiral heat dissipation channel 7. The top of the tube body 1 is snapped with a top cover 8. A tensioning component 9 is fixedly installed on one side inside the top cover 8. By setting the tensioning component 9, the yarn is passed through the threading ring 902. The hydraulic rod 901 is opened, which drives the threading ring 902 to tighten the yarn, compensate for the elasticity of the yarn, and prevent the yarn from loosening during winding.

[0030] The composite coating group 6 includes a nano-ceramic particle coating 601 and an ultra-thin carbon nanotube coating 602. The nano-ceramic particle coating 601 is coated on the surface of the anti-slip layer 5, and the ultra-thin carbon nanotube coating 602 is coated on the surface of the nano-ceramic particle coating 601.

[0031] By setting the composite coating group 6, the anti-slip layer 5 and the nano-ceramic particle coating 601 can increase the friction between the yarn and the winding tube 1, making it less likely to slip or detach when winding the yarn, and facilitating the winding of the yarn. The ultra-thin carbon nanotube coating 602 can eliminate static electricity and prevent static electricity accumulation caused by friction when winding the yarn at high speed.

[0032] The tensioning assembly 9 includes a hydraulic rod 901 and a threading ring 902. The hydraulic rod 901 is fixedly installed on one side inside the top cover 8, and the threading ring 902 is fixedly installed at the output end of the hydraulic rod 901.

[0033] By setting the tensioning component 9, the yarn is passed through the threading ring 902, the hydraulic rod 901 is opened, and the threading ring 902 is driven to tighten the yarn, compensate for the yarn elasticity, and prevent the yarn from loosening during winding.

[0034] There are several spiral heat dissipation channels 7, which are arranged in a ring array from top to bottom.

[0035] The spiral heat dissipation channel 7 facilitates heat dissipation when the yarn is wound at high speed.

[0036] There are four sets of cavities and four sets of reinforcing ribs 4, which are arranged in a ring array on the inner wall of the tube body 1.

[0037] The reinforcing rib 4 is designed to improve the structural strength of the tube body 1 and prevent deformation.

[0038] Both the anti-slip layer 5 and the composite coating group 6 have heat dissipation holes on their surfaces, which are adapted to the spiral heat dissipation channel 7.

[0039] The design of the heat dissipation holes and spiral heat dissipation channels 7 facilitates heat dissipation.

[0040] The anti-slip layer 5 is made of polylactic acid modified silicone. The anti-slip layer 5 increases the friction with the yarn.

[0041] In this invention, the working steps of the device are as follows:

[0042] First step: The upper reinforcing ring 3, the lower reinforcing ring 2, and the reinforcing rib 4 improve the overall structural strength of the coiled tube body 1, making it less prone to deformation and with a long service life;

[0043] The second step: the anti-slip layer 5 and the nano-ceramic particle coating 601 can increase the friction between the yarn and the winding tube 1, making it less likely to slip or come off when winding the yarn, and making it easier to wind the yarn. The ultra-thin carbon nanotube coating 602 can eliminate static electricity and prevent static electricity from accumulating during high-speed winding of the yarn.

[0044] Third step: Pass the yarn through the threading ring 902, open the hydraulic rod 901, and drive the threading ring 902 to tighten the yarn, compensate for the yarn elasticity, and prevent the yarn from loosening during winding.

[0045] It should be noted that the device structure and accompanying drawings of this utility model mainly describe the principle of this utility model. In terms of the technical aspects of this design principle, the setting of the power mechanism, power supply system and control system of the device is not fully described. However, under the premise that those skilled in the art understand the principle of the above utility model, the specific structure of its power mechanism, power supply system and control system can be clearly understood. The control method in the application document is automatic control through a controller. The control circuit of the controller can be implemented by those skilled in the art through simple programming.

[0046] All standard parts used can be purchased from the market, and can be customized according to the instructions and drawings. The specific connection methods of each part adopt conventional methods such as bolts, rivets, and welding that are mature in the existing technology. The machinery, parts and equipment adopt conventional models in the existing technology, and the structure and principle of the components known to those skilled in the art can be known by those skilled in the art through technical manuals or conventional experimental methods.

[0047] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A conical textile tube, comprising a tube body (1), characterized in that: The bottom surface of the tube body (1) is fixedly provided with a lower reinforcing ring (2), the top surface of the tube body (1) is fixedly provided with an upper reinforcing ring (3), the inner wall of the tube body (1) is provided with a cavity, the cavity is fixedly provided with a reinforcing rib (4), the surface of the tube body (1) is fixedly provided with an anti-slip layer (5), the surface of the anti-slip layer (5) is coated with a composite coating group (6), the surface of the tube body (1) is provided with a spiral heat dissipation channel (7), the top of the tube body (1) is snapped with a top cover (8), and a tensioning component (9) is fixedly installed on one side inside the top cover (8).

2. The tapered textile tube according to claim 1, characterized in that: The composite coating group (6) includes a nano-ceramic particle coating (601) and an ultra-thin carbon nanotube coating (602). The nano-ceramic particle coating (601) is coated on the surface of the anti-slip layer (5), and the ultra-thin carbon nanotube coating (602) is coated on the surface of the nano-ceramic particle coating (601).

3. The tapered textile tube according to claim 1, characterized in that: The tensioning assembly (9) includes a hydraulic rod (901) and a threading ring (902). The hydraulic rod (901) is fixedly installed on one side inside the top cover (8), and the threading ring (902) is fixedly installed at the output end of the hydraulic rod (901).

4. The tapered textile tube according to claim 1, characterized in that: The number of spiral heat dissipation channels (7) is several, and the several spiral heat dissipation channels (7) are arranged in a ring array from top to bottom.

5. A tapered textile tube according to claim 1, characterized in that: The number of cavities and reinforcing ribs (4) is four sets, and the four sets of cavities and reinforcing ribs (4) are arranged in a ring array on the inner wall of the tube body (1).

6. A tapered textile tube according to claim 1, characterized in that: The surfaces of the anti-slip layer (5) and the composite coating group (6) are provided with heat dissipation holes, which are adapted to the spiral heat dissipation channel (7).

7. A tapered textile tube according to claim 1, characterized in that: The anti-slip layer (5) is made of polylactic acid modified silicone.