CN218928827U - Shading antibacterial spring spinning - Google Patents

Abstract

The utility model discloses a shading antibacterial spring spinning, which relates to the technical field of spinning and aims at solving the problems of poor air permeability and moisture removal performance of sunshade face yarns and easiness in breeding bacteria, and the technical scheme is as follows: the novel wet-type fabric comprises a wet-guiding layer and a wet-exhausting layer, wherein a plurality of wet-guiding holes are obliquely formed in the surface of the wet-guiding layer towards the wet-exhausting layer, a plurality of wet-guiding fluff is arranged on the surface of the wet-exhausting layer, the wet-guiding fluff is irregularly inserted into the wet-guiding holes, and the wet-guiding fluff is formed by twisting a plurality of polypropylene fibers. The shading and bacteriostasis spring spinning achieves the technical effects of shading and bacteriostasis by using the polypropylene fiber and the viscose fiber.

Description

Shading antibacterial spring spinning

Technical Field

The utility model relates to the technical field of spinning, in particular to shading antibacterial spring spinning.

Background

Spring spinning fabric is a long-appearing old variety, but in recent years, the textile world in the glossy area changes the edition of the product, besides adopting extinction yarn raw materials and weaving process innovation, the dyeing and finishing post-treatment process is also extended, the density is increased, the hand feeling is softer, and the functions are more expanded.

The sun-shading face yarn is made of clothing which is selected by a girl to shade the face by exposing sun in summer, the common sun-shading face yarn is made of spring spun or terylene blended fabrics, silk fibers are adopted for ensuring coolness, but the sun-shading face yarn made of any material is weak in moisture absorption capacity, the sun-shading face yarn is made of heat-insulating cool sun-shading materials for increasing the light blocking capacity of the sun-shading face yarn, the sun-shading face yarn is worn on the parts which are prone to generating moisture, such as the mouth and nose, due to the fact that the air permeability and the moisture absorption of the face yarn are insufficient, a large amount of water vapor is accumulated in the sun-shading face yarn due to air impermeability, a moist ring-shaped structure is formed on the surface of the sun-shading face yarn, so that the sanitary condition of the sun-shading face yarn is greatly reduced, and the sun-shading face yarn in the prior art has the problem that bacteria are prone to generating due to insufficient air permeability and moisture permeability.

There is therefore a need to propose a new solution to this problem.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model aims to provide the shading antibacterial spring spinning, which has the effects of increasing the moisture-conducting and moisture-removing capacity of sunshade yarns and preventing bacterial proliferation through the arrangement of the structure.

The technical aim of the utility model is realized by the following technical scheme: the utility model provides a shading antibacterial spring is spun, includes wet layer and moisture removal layer, wet layer surface orientation the wet layer slope has seted up a plurality of wet holes that lead, moisture removal layer surface is provided with a plurality of wet fluff that lead, a plurality of wet fluff irregularly insert a plurality of in the wet hole that leads, a plurality of wet fluff is twisted with one another by a plurality of polypropylene fibre and forms.

The utility model is further provided with: the wet discharging layer is divided into a wet guiding part and a wet discharging part, and a plurality of through holes are distributed on the surface of the wet discharging part in an array manner.

The utility model is further provided with: the wet removing part is formed by knitting a plurality of wet removing yarn warps and wefts, the through hole tissue is 6-page healds, warp floating points are floating, weft floating points are sinking, and the through hole tissue is circularly formed by the tissue from left to right from bottom to top: a floating, sinking, floating and sinking sinking, floating, sinking, floating, sinking and sinking sinking and floating.

The utility model is further provided with: the moisture removing yarn is formed by twisting viscose fibers and viscose special-shaped cross-section fibers, the cross section of the viscose special-shaped cross-section fibers is three-leaf-shaped, and three non-closed cavities are formed in the viscose special-shaped cross-section fibers.

The utility model is further provided with: the wet guiding part is formed by warp and weft knitting of first composite yarns and second composite yarns, the reinforced satin weave is 8-page heald, floating points of warp and weft are floating, floating points of weft are sinking, and the loop of the reinforced satin weave from left to right from bottom to top is as follows: sinking, floating, sinking, floating and sinking floating, sinking sinking, floating and sinking sinking, floating, sinking, floating, sinking and sinking.

The utility model is further provided with: the first composite yarn is formed by a core yarn and a cladding yarn cladding the core yarn, the core yarn is formed by twisting a plurality of polypropylene fibers, the cladding yarn is formed by twisting a plurality of polypropylene fiber special-shaped section fibers, the section of the polypropylene fiber special-shaped section fibers is cross-shaped, and the second composite yarn is formed by twisting polyester fibers and silk fibers which are wound by the polyester fibers.

The utility model is further provided with: the moisture removal layer is woven into a plain weave through warps and wefts of a plurality of third composite yarns, and the third composite yarns are formed by twisting a plurality of polypropylene fibers and a plurality of polyester fibers.

In summary, the utility model has the following beneficial effects: the wet-conducting layer and the wet-draining layer are arranged, sweat on the surface of the fabric can be transferred away by the wet-conducting layer, the wet-draining layer can drain the moisture conducted by the wet-conducting layer out of the fabric, a plurality of wet-conducting holes are obliquely formed in the surface of the wet-conducting layer towards the wet-draining layer, the moisture can be effectively conducted by gravity through the inclined arrangement, the wet-conducting effect of the wet-conducting layer is enhanced, a plurality of wet-conducting fluff is arranged on the surface of the wet-draining layer, the wet-conducting fluff is irregularly inserted into the plurality of wet-conducting holes, the moisture on the surface of the wet-conducting layer can be conducted into the wet-draining layer through the wet-conducting fluff, the wet-conducting efficiency of the fabric is accelerated, the wet-conducting fluff is formed by twisting a plurality of polypropylene fibers, the wet-conducting capability of the polypropylene fibers is further enhanced, the wet-conducting effect of the wet-conducting fluff can be conducted rapidly, the wet-conducting effect of the wet-conducting layer is further enhanced, and the technical effect of the fabric with the wet-conducting capability is achieved.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is an organizational chart of the through-hole tissue of the present utility model;

FIG. 3 is a schematic diagram of the weave architecture for reinforcing satin weave according to the present utility model;

FIG. 4 is a cross-sectional view of a moisture wicking fluff of the present utility model;

FIG. 5 is a cross-sectional view of a moisture removing yarn of the present utility model;

FIG. 6 is a cross-sectional view of a first composite yarn of the present utility model;

FIG. 7 is a cross-sectional view of a second composite yarn of the present utility model;

FIG. 8 is a cross-sectional view of a third composite yarn of the present utility model;

in the figure: 1. a moisture-conducting layer; 2. a moisture-conducting part; 3. a moisture removing part; 4. a through hole; 5. a moisture guiding hole; 6. moisture-conducting fluff; 7. a polypropylene fiber; 8. viscose fiber; 9. viscose special-shaped cross-section fiber; 10. a moisture removing yarn; 11. a core yarn; 12. covering yarn; 13. polypropylene fiber with special-shaped cross section; 14. a first composite yarn; 15. polyester fiber; 16. silk fibers; 17. a second composite yarn; 18. and a third composite yarn.

Detailed Description

The present utility model will be described in detail below with reference to the accompanying drawings and examples.

A shading antibacterial spring spinning, as shown in figure 1, comprises a moisture guiding layer 1 and a moisture removing layer, wherein a plurality of moisture guiding holes 5 are obliquely formed in the surface of the moisture guiding layer 1 towards the moisture removing layer, and a plurality of moisture guiding fluff 6 are arranged on the surface of the moisture removing layer.

As shown in fig. 1-8, the viscose fiber 8 is arranged on a spinneret plate to form viscose special-shaped cross-section fiber 9, the cross section of the viscose special-shaped cross-section fiber 9 is three-leaf-shaped, three non-closed cavities are formed in the viscose special-shaped cross-section fiber 9, the viscose fiber 8 has strong water absorption, three non-closed water storage cavities are formed in the viscose special-shaped cross-section fiber 9, the water absorption capacity of the viscose fiber 8 can be enhanced, the viscose fiber 8 can be effectively discharged, the water absorption capacity of the viscose fiber 8 is enhanced, the viscose fiber 8 and the viscose special-shaped cross-section fiber 9 are placed in a twisting machine to form a moisture removing yarn 10, and the moisture removing yarn 10 has strong water absorption.

As shown in fig. 1 to 8, a plurality of moisture removing yarns 10 are put into a shuttle loom to be warp and weft knitted to form a moisture removing part 3 and form a through hole structure, the through hole structure is 6-page healds, warp floating points are floating, weft floating points are sinking, and the through hole structure circulates from left to right from bottom to top as follows: the surface of the wet discharging part 3 is integrally formed with a plurality of through holes 4, when the wet discharging part 3 absorbs enough moisture, the moisture can be volatilized into the air directly, the contact area between the fabric and the air is enlarged by the through holes 4, and the moisture discharging capability of the fabric is enhanced.

As shown in fig. 1-8, the polypropylene fiber 7 is placed in a twisting machine to form a polypropylene special-shaped cross-section fiber 13, the cross section of the polypropylene special-shaped cross-section fiber 13 is cross-shaped, channels for moisture to pass through exist among the fibers of the cross-shaped polypropylene special-section fiber 13, so that the moisture transportation efficiency among the fibers is enhanced, the moisture guiding capacity of the polypropylene fiber 7 is enhanced, a plurality of polypropylene special-shaped cross-section fibers 13 are placed in the twisting machine to form a covering yarn 12, a plurality of polypropylene fibers 7 are placed in the twisting machine to form a core yarn 11, the core yarn 11 and the covering yarn 12 are placed in a ring twisting machine to form a first composite yarn 14, the first composite yarn 14 has strong moisture guiding capacity, the polyester fiber 15 and a plurality of silk fibers 16 are placed in the ring twisting machine to form a second composite yarn 17, the polyester fiber 15 has strong fiber strength, the silk fiber 16 has cool touch, and therefore the structural strength of the sun-shading face yarn and the touch feeling of the face fabric surface are enhanced, and the comfort of the face fabric is enhanced.

As shown in fig. 1 to 8, the first composite yarn 14 and the second composite yarn 17 are put into a shuttle loom, the wet guiding part 2 is woven and formed into a reinforced satin weave, the reinforced satin weave is 8-page heald, the warp floating point is floating, the weft floating point is sinking, and the circulation of the reinforced satin weave from left to right, from bottom to top is: the fabric has stronger fiber strength on the surface, smooth and comfortable surface, good moisture conducting capability, and achieves the technical effects of good hand feeling and strong moisture conducting capability.

As shown in fig. 1-8, a plurality of polypropylene fibers 7 and a plurality of polyester fibers 15 are put into a twisting machine to form a third composite yarn 18, the third composite yarn 18 has stronger toughness and wet guiding capacity, the third composite yarn 18 is put into a shuttle loom to be woven into a wet draining layer and form a plain weave, the surface smoothness of the fabric is ensured, the wet draining layer is put into a laser perforating machine to incline out a plurality of wet guiding holes 5, the plurality of polypropylene fibers 7 are put into the twisting machine to be twisted, the formed polypropylene fibers are put into a fiber cutting machine to form a plurality of polypropylene staple fibers, a plurality of viscous liquid is dripped into the surface of the wet draining layer and a plurality of polypropylene staple fibers are directionally sprayed on the surface of the fabric to form a plurality of wet guiding fluff 6, after the viscous liquid is dried, the surface of the wet draining layer is pressed into the wet guiding fluff 6 along the reverse direction of the sprayed polypropylene staple fibers, the short threads on the surface of the wet draining layer are in a temporary upright state under the action of steam and high temperature, the wet guiding holes 5 are formed, and the wet guiding holes are formed in an upright state, and the wet guiding layer is formed.

When the fabric is made into the sunshade face yarn, sweat on the surface of the moisture-conducting layer 1 can be conducted into the moisture-draining layer through the moisture-conducting through holes 4 or conducted into the moisture-conducting fluff 6 to enter the moisture-draining layer, and is conducted into the moisture-draining part 3 in the moisture-conducting part 2 on the surface of the moisture-draining layer to be absorbed by the fibers of the moisture-draining part 3, and when the liquid absorption amount of the moisture-draining part 3 reaches saturation, the sweat can volatilize from the inside of the through holes 4, so that the technical effect of discharging the sweat on the surface of the moisture-conducting layer 1 out of the fabric is achieved, the spatial dryness of the sunshade face yarn facing to one face is ensured, the growth of bacteria is inhibited, and the technical effect of shading and bacteriostasis is achieved.

The above description is only a preferred embodiment of the present utility model, and the protection scope of the present utility model is not limited to the above examples, and all technical solutions belonging to the concept of the present utility model belong to the protection scope of the present utility model. It should be noted that modifications and adaptations to the present utility model may occur to one skilled in the art without departing from the principles of the present utility model and are intended to be within the scope of the present utility model.

Claims (7)

1. A shading antibacterial spring spinning, which is characterized in that: including wet layer (1) and moisture removal layer, wet layer (1) surface orientation moisture removal layer slope has seted up a plurality of wet holes (5), moisture removal layer surface is provided with a plurality of wet naps (6), a plurality of wet naps (6) insert a plurality of in wet hole (5), a plurality of wet naps (6) are twisted with one another by a plurality of polypropylene fibre (7) and are formed.

2. The lightproof bacteriostatic spring spinning according to claim 1, characterized in that: the wet discharging layer is divided into a wet guiding part (2) and a wet discharging part (3), and a plurality of through holes (4) are distributed on the surface of the wet discharging part (3) in an array mode.

3. The lightproof bacteriostatic spring spinning according to claim 2, characterized in that: the wet removing part (3) is knitted by warps and wefts of a plurality of wet removing yarns (10) to form a through hole tissue, the through hole tissue is 6-page healds, warp floating points are floating, weft floating points are sinking, and the through hole tissue circulates from left to right from bottom to top: a floating, sinking, floating and sinking sinking, floating, sinking, floating, sinking and sinking sinking and floating.

4. A lightproof bacteriostatic spring spin according to claim 3, characterized in that: the moisture removing yarn (10) is formed by twisting viscose fibers (8) and viscose profiled cross-section fibers (9), and the cross section of the viscose profiled cross-section fibers (9) is three-leaf-shaped and three non-closed cavities are formed in the viscose profiled cross-section fibers.

5. The lightproof bacteriostatic spring spinning according to claim 2, characterized in that: the wet guiding part (2) is knitted by warps and wefts of the first composite yarn (14) and the second composite yarn (17) to form a reinforced satin weave, the reinforced satin weave is 8-page healds, the warp floating points are floating, the weft floating points are sinking, and the reinforced satin weave circulates from left to right from bottom to top to the weave as follows: sinking, floating, sinking, floating and sinking floating, sinking sinking, floating and sinking sinking, floating, sinking, floating, sinking and sinking.

6. The light-shielding bacteriostatic spring spun of claim 5, wherein: the first composite yarn (14) is formed by a core yarn (11) and a cladding yarn (12) wrapping the core yarn (11), the core yarn (11) is formed by twisting a plurality of polypropylene fiber (7), the cladding yarn (12) is formed by twisting a plurality of polypropylene fiber special-shaped section fibers (13), the section of the polypropylene fiber special-shaped section fibers (13) is cross-shaped, and the second composite yarn (17) is formed by twisting polyester fiber (15) and silk fiber (16) wrapping the polyester fiber (15).

7. The lightproof bacteriostatic spring spinning according to claim 1, characterized in that: the moisture removal layer is woven by warps and wefts of a plurality of third composite yarns (18) to form a plain weave, and the third composite yarns (18) are formed by twisting a plurality of polypropylene fibers (7) and a plurality of polyester fibers (15).

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