CN220742378U - Wear-resistant antistatic plain cloth - Google Patents

Abstract

The utility model discloses wear-resistant antistatic level cloth, which comprises a first plain weave fabric layer, a waterproof moisture-permeable film and a second plain weave fabric layer which are compounded; the first plain weave fabric layer is formed by interweaving bio-based nylon DTY filaments and graphene fiber yarns which are twisted in parallel according to plain weave; the second flat grain fabric layer is formed by interweaving copper ammonia fiber yarns and antibacterial fiber yarns which are twisted in a phase-by-phase manner with polylactic acid fiber filaments and conductive polylactic acid fiber yarns which are twisted in a phase-by-phase manner according to a plain weave; the polylactic acid fiber filaments have grooves along the surface in the longitudinal direction. The nylon fiber is used in the first plain fabric layer, so that the first plain fabric layer has good wear resistance, and the graphene fiber is used, so that the fabric has good antistatic effect. Copper ammonia fiber is used in the second flat pattern fabric layer, so that the skin-friendly performance of the second flat pattern fabric layer is improved, and the polylactic acid filament with grooves on the surface has certain moisture absorption and moisture conduction performance.

Description

Wear-resistant antistatic plain cloth

Technical Field

The utility model relates to wear-resistant antistatic plain cloth, and belongs to the technical field of textile fabrics.

Background

With the improvement of the living standard of people, the requirements on the fabric of the textile are higher and higher, and textile products with different performances and different styles become a new trend of the world textile market. The prior art adopts the techniques of differentiated warp and weft materials, special weaving process, dyeing and finishing process and the like to realize textile products with different fashions. With the importance of people on health, the textile has comfort and needs to be added with special functions to meet the demands of different people.

The prior clothing generally contains chemical fiber synthetic fibers as raw materials to meet the requirements of clothing fabrics on strength and the like. However, when the chemical fiber fabric is used, static electricity can be generated due to mutual friction among fibers, so that the clothes are entangled and stuck, dust is absorbed in a large amount, discharge sparks are generated when the clothes are worn and taken off, even human body electric shock phenomenon occurs, personal injury is caused, and discharge is generated when people contact with people or objects, so that the human body is endangered, and the body health of people is influenced. The fabric can generate friction in use, static electricity can be generated by friction, and the fabric can be worn, so that the fabric with antistatic performance and good wear resistance is needed.

Disclosure of Invention

The utility model aims to provide wear-resistant antistatic tattoo, nylon fibers adopted by the wear-resistant antistatic tattoo provide good wear resistance for the fabric, and graphene fiber yarns used by the wear-resistant antistatic tattoo can improve the antistatic effect of the fabric.

In order to solve the technical problems, the aim of the utility model is realized as follows:

the utility model relates to wear-resistant antistatic level cloth, which comprises a first plain weave fabric layer, a waterproof moisture-permeable film and a second plain weave fabric layer which are compounded;

the first plain weave fabric layer is formed by interweaving first warp yarns and first weft yarns according to a plain weave, and the first warp yarns are biobased nylon filaments; the first weft yarn is a biobased nylon DTY filament yarn and a graphene fiber yarn which are twisted in parallel;

the second flat grain fabric layer is formed by interweaving second warp yarns and second weft yarns according to a plain weave, the second warp yarns are copper ammonia fiber yarns and antibacterial fiber yarns which are twisted in parallel, and the second weft yarns are polylactic acid fiber filaments and conductive polylactic acid fiber yarns which are twisted in parallel; the polylactic acid fiber filaments have grooves along the surface in the length direction.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: the fiber used in the graphene fiber yarn is fibrilia, and graphene is attached to the surface of the fibrilia.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: the cross section of the polylactic acid fiber filament is in a cross shape or a Y shape.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: the fiber used in the antibacterial fiber yarn is nano antibacterial viscose fiber.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: the waterproof and moisture-permeable membrane is a PTFE microporous membrane or a TPU microporous membrane.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: an ultraviolet-proof fabric layer is arranged between the first plain fabric layer and the waterproof moisture-permeable film.

The beneficial effects of the utility model are as follows: according to the wear-resistant antistatic tattoo, the nylon fiber is used in the first plain fabric layer to enable the first plain fabric layer to have good wear resistance, and the graphene fiber is used to enable the fabric to have good antistatic effect. Copper ammonia fiber is used in the second flat pattern fabric layer, so that the skin-friendly performance of the second flat pattern fabric layer is improved, and the polylactic acid filament with grooves on the surface has certain moisture absorption and moisture conduction performance.

Drawings

FIG. 1 is a schematic view of a wear-resistant antistatic pattern cloth according to an embodiment;

fig. 2 is a schematic structural view of a wear-resistant antistatic pattern cloth according to a second embodiment.

The labels in the figures are illustrated below: 1-a first plain weave fabric layer; 2-a waterproof moisture-permeable film; 3-a second flat pattern layer; 4-ultraviolet resistant fabric layer.

Detailed Description

The utility model will be further described with reference to the drawings and specific examples.

Example 1

This embodiment will be described in detail with reference to fig. 1. The wear-resistant antistatic plain weave fabric according to the embodiment comprises a first plain weave fabric layer 1, a waterproof moisture-permeable film 2 and a second plain weave fabric layer 3 which are compounded; and is compounded by a hot melt adhesive net film.

The plain weave fabric layer 1 is formed by interweaving first warp yarns and first weft yarns according to a plain weave, wherein the first warp yarns are biobased nylon filaments; the first weft yarn is a biobased nylon DTY filament yarn and a graphene fiber yarn which are twisted in parallel. The bio-based nylon filament, namely the bio-based nylon 56, has the advantages of strong hygroscopicity and skin affinity, so that the bio-based nylon filament has a wide application prospect. The bio-based nylon blended fabric has excellent low-temperature dyeing performance, and compared with nylon fabric, the dyeing degree is deeper and more vivid.

Further, the fiber used in the graphene fiber yarn is fibrilia, and graphene is attached to the surface of the fibrilia. The fibrilia is particularly flax fiber, and can provide good hygroscopicity and moisture release effect. Can improve the stiffness of the fabric.

The second flat pattern fabric layer is formed by interweaving second warp yarns and second weft yarns according to a plain weave, the second warp yarns are copper ammonia fiber yarns and antibacterial fiber yarns which are twisted in parallel, and the second weft yarns are polylactic acid fiber filaments and conductive polylactic acid fiber yarns which are twisted in parallel; the polylactic acid fiber filaments have grooves along the surface in the length direction. The section of the copper ammonia fiber is circular, no skin-core structure exists, the fiber can bear high stretching, and the prepared monofilament is thinner, so that the fabric has soft hand feeling, soft luster and real silk feeling. The clothing has good wear performance, good hygroscopicity, draping feel, and the wear performance similar to that of silk, and meets the trend of environment-friendly clothing.

Further, the cross section of the polylactic acid fiber filament is in a cross shape or a Y shape. In this embodiment, Y-shaped is selected. The surface of the polylactic acid filament with the special-shaped cross section is provided with grooves along the length direction, has a wicking effect and has a good moisture absorption effect, so that the second flat-grain fabric layer 2 can be kept dry, and wearing comfort is improved.

Further, the fiber used in the antibacterial fiber yarn is nano antibacterial viscose fiber. Providing a good antibacterial effect for the second flat pattern fabric layer 2.

Further, the waterproof and moisture-permeable membrane 2 is a PTFE microporous membrane or a TPU microporous membrane. The TPU microporous membrane is selected in the embodiment, and has good waterproof and moisture permeable effects.

Example two

This embodiment will be described in detail with reference to fig. 2. The difference between the wear-resistant antistatic level cloth according to the first embodiment and the first embodiment is that: an ultraviolet-proof fabric layer 4 is arranged between the first plain fabric layer 1 and the waterproof and moisture-permeable film 2. The ultraviolet-proof fabric 4 is formed by interweaving ultraviolet-proof nylon filaments. The fabric has good protective effect when being used in a high ultraviolet region.

The foregoing describes in detail preferred embodiments of the present utility model. It should be understood that numerous modifications and variations can be made in accordance with the concepts of the utility model by one of ordinary skill in the art without undue burden. Therefore, all technical solutions which can be obtained by logic analysis, reasoning or limited experiments based on the prior art by the person skilled in the art according to the inventive concept shall be within the scope of protection defined by the claims.

Claims (6)

1. The wear-resistant antistatic level cloth is characterized by comprising a first plain weave fabric layer (1), a waterproof moisture-permeable membrane (2) and a second plain weave fabric layer (3) which are compounded;

the first plain weave fabric layer (1) is formed by interweaving first warp yarns and first weft yarns according to plain weave, and the first warp yarns are bio-based nylon filaments; the first weft yarn is a biobased nylon DTY filament yarn and a graphene fiber yarn which are twisted in parallel;

the second flat grain fabric layer is formed by interweaving second warp yarns and second weft yarns according to a plain weave, the second warp yarns are copper ammonia fiber yarns and antibacterial fiber yarns which are twisted in parallel, and the second weft yarns are polylactic acid fiber filaments and conductive polylactic acid fiber yarns which are twisted in parallel; the polylactic acid fiber filaments have grooves along the surface in the length direction.

2. The wear-resistant antistatic tattoo according to claim 1, wherein the fiber used in the graphene fiber yarn is a fibrilia, and graphene is attached to the surface of the fibrilia.

3. The wear-resistant antistatic tattoo according to claim 1, wherein the cross section of the polylactic acid fiber filaments is cross-shaped or Y-shaped.

4. The abrasion resistant antistatic tattoo according to claim 1, wherein said antimicrobial fiber yarns are nano antimicrobial viscose.

5. The wear-resistant antistatic tattoo according to claim 1, wherein the waterproof moisture-permeable membrane (2) is a PTFE or TPU microporous membrane.

6. A wear-resistant antistatic pattern cloth according to any one of claims 1 to 5, characterized in that an anti-uv pattern layer (4) is arranged between the first plain weave fabric layer (1) and the waterproof moisture-permeable membrane (2).