CN220242649U - Antistatic polyester-cotton blended fabric - Google Patents

Abstract

The utility model discloses an antistatic polyester-cotton blended fabric, which comprises a polyester-cotton blended fabric layer; one side of the polyester-cotton blended fabric layer is compounded with an antistatic fabric layer, and the other side of the polyester-cotton blended fabric layer is compounded with a polyester-nylon fabric layer; the antistatic fabric layer is formed by interweaving polyaniline conductive yarns and silk conductive yarns serving as warp and weft yarns, and the silk conductive yarns comprise degummed silk yarns and PANI/PVA conductive layers coated on the outer sides of the degummed silk yarns. According to the antistatic polyester-cotton blended fabric, the polyester-nylon fabric layer gives the good wear-resisting effect to the blended fabric, and the silk-like conductive yarns are used in the antistatic fabric layer, so that the fabric has good antistatic effect, good skin-friendly effect and improved use effect when being used as a garment fabric.

Description

Antistatic polyester-cotton blended fabric

Technical Field

The utility model relates to an antistatic polyester-cotton blended fabric, and belongs to the technical field of textile fabrics.

Background

The polyester fiber has the advantages of high modulus, high strength, high elasticity, good shape retention, heat resistance and the like, and becomes the synthetic fiber variety with the widest application and the largest consumption. Because the polyester fiber has small hygroscopicity and is easy to generate static electricity when rubbed with other fibers, the common solution is to blend the polyester fiber with the cotton fiber, and the cotton fiber has good moisture absorption effect, so that the friction electrification phenomenon of the polyester fiber can be reduced. Polyester and nylon are two types of fibers with better wear resistance in common chemical synthetic fibers. The fabric prepared from the polyester-cotton blended yarn can reduce the performance of the fabric in the aspects of skin-friendly performance and wear-resistant performance. How to make the terylene blended fabric have good antistatic effect and good skin-friendly and wear-resistant effects becomes the problem to be solved.

Disclosure of Invention

The utility model aims to provide an antistatic polyester-cotton blended fabric which has good skin-friendly effect and wear-resistant effect on the premise of good antistatic performance.

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

the utility model relates to an antistatic polyester-cotton blended fabric, which comprises a polyester-cotton blended fabric layer; one side of the polyester-cotton blended fabric layer is compounded with an antistatic fabric layer, and the other side of the polyester-cotton blended fabric layer is compounded with a polyester-nylon fabric layer;

the antistatic fabric layer is formed by interweaving polyaniline conductive yarns and silk conductive yarns serving as warp and weft yarns, and the silk conductive yarns comprise degummed silk yarns and PANI/PVA conductive layers coated on the outer sides of the degummed silk yarns.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: the polyester cotton blended fabric layer is formed by interweaving polyester cotton core-spun yarns, and the polyester cotton core-spun yarns comprise high-strength polyester filaments serving as core yarns and polyester cotton mixed fiber layers coated on the outer sides of the core yarns.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: the polyester-nylon fabric layer is formed by interweaving polyester filaments serving as warp yarns and superfine polyester-nylon mixed filaments serving as weft yarns according to weft surface tissues.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: the anti-static fabric layer is characterized in that polyaniline conductive yarns in the anti-static fabric layer are used as warp yarns and silk conductive yarns as weft yarns, the anti-static fabric layer is formed by interweaving warp surface tissues, and one side of the warp surface is close to one side of the polyester-cotton blended fabric layer.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: one side of the polyester-nylon fabric layer, which is far away from the polyester-cotton blended fabric layer, is provided with a polyurethane coating.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: an antibacterial fabric layer is compounded between the antistatic fabric layer and the polyester-cotton blended fabric layer 1.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: the antibacterial fabric layer is formed by interweaving apocynum fiber yarns with silver ions attached to the surfaces.

The beneficial effects of the utility model are as follows: according to the antistatic polyester-cotton blended fabric, the polyester-nylon fabric layer gives the good wear-resisting effect to the blended fabric, and the silk-like conductive yarns are used in the antistatic fabric layer, so that the fabric has good antistatic effect, good skin-friendly effect and improved use effect when being used as a garment fabric.

Drawings

Fig. 1 is a schematic structural diagram of an antistatic polyester-cotton blended fabric according to an embodiment;

FIG. 2 is a schematic diagram of a silk conductive yarn;

fig. 3 is a schematic structural diagram of an antistatic polyester-cotton blended fabric according to a second embodiment.

The labels in the figures are illustrated below: 1-polyester cotton blended fabric layer; 2-an antistatic fabric layer; 3-polyester-nylon fabric layer; 21-degummed silk yarn; 22-PANI/PVA conductive layer; 4-polyurethane coating; 5-antibacterial fabric layer.

Detailed Description

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

Example 1

The present embodiment will be described in detail with reference to fig. 1 and 2. The antistatic polyester-cotton blended fabric comprises a polyester-cotton blended fabric layer 1; one side of the polyester-cotton blended fabric layer 1 is compounded with an antistatic fabric layer 2, and the other side is compounded with a polyester-nylon fabric layer 3. The antistatic fabric layer 2 provides a good antistatic effect for the blended fabric, and the polyester fibers and the nylon fibers used by the polyester-nylon fabric layer 3 have good wear-resisting effects, so that good wear-resisting performance is provided for the blended fabric. And the polyester cotton fabric layer 1 and the antistatic fabric layer 2 and the polyester nylon fabric layer 3 are compounded through a hot melt adhesive net film.

The antistatic fabric layer 2 is formed by interweaving polyaniline conductive yarns and degummed silk conductive yarns as warp and weft yarns, and the silk conductive yarns comprise degummed silk yarns 21 and PANI/PVA conductive layers 22 coated on the outer sides of the silk yarns. Polyaniline PANI contains alternating benzene rings and nitrogen atoms in the backbone, which is a special conductive polymer. The pi electrons have delocalization capability, the structure of the pi electrons can form a large number of conjugated pi electrons, the delocalization of the electrons is enhanced, and the movable range is enlarged, so that the compound has the function of conducting electricity. The method can be mainly applied to photoelectrochemical cells, rechargeable batteries, electromagnetic shielding materials and the like at present. Polyvinyl alcohol (PVA) is a commonly used toughening material, commonly used for toughening PANI. The elongation at break of the PANI film can be improved by more than 20 times by using a proper amount of PVA, and the flexibility of the PANI conductive layer is greatly improved so as to improve the durability of the PANI conductive layer.

Furthermore, the polyester-nylon fabric layer 3 is formed by interweaving polyester filaments serving as warp yarns and superfine polyester-nylon mixed filaments serving as weft yarns according to weft surface tissues. And one warp side of the polyester-nylon fabric layer 3 is compounded with the polyester-cotton blended fabric layer 1. The superfine polyester-nylon mixed filament comprises superfine polyester multifilament yarn and fine denier nylon 6 multifilament yarn which are arranged in parallel and intertwined through network points. The fineness of the superfine polyester multifilament is 75-100D/144-288F; the fineness of the fine denier nylon 6 multifilament is 35-60D/48-96F. Specifically, in the present embodiment, the fineness of the ultra-fine polyester multifilament is 75D/288F; the fineness of the fine denier nylon 6 multifilament is 35D/48F. The superfine polyester multifilament and the fine denier nylon 6 multifilament are fed into a network nozzle in parallel, and are intertwined through high-temperature air flow, so that the superfine polyester multifilament and the fine denier nylon 6 multifilament are fixed. The entanglement points formed are network points, the number of network points per meter length being referred to as the degree of network, in this embodiment 40-50 per meter, in this embodiment 45 per meter.

Further, the polyester-cotton blended fabric layer 1 is formed by interweaving polyester-cotton core-spun yarns, and the polyester-cotton core-spun yarns comprise high-strength polyester filaments serving as core yarns and polyester-cotton mixed fiber layers coated on the outer sides of the core yarns. The high-strength polyester filament yarn can provide good strength for the polyester-cotton blended fabric.

Furthermore, the polyaniline conductive yarn in the antistatic fabric layer 2 is used as warp yarn and the silk conductive yarn is used as weft yarn, and is interwoven according to the warp surface texture, and one side of the warp surface is close to one side of the polyester-cotton blended fabric layer 1, and one side of the weft surface is close to a user.

Example two

This embodiment will be described in detail with reference to fig. 3. The difference between the antistatic polyester cotton blended fabric related to the embodiment and the embodiment one is that: one side of the polyester-nylon fabric layer 3 far away from the polyester-cotton blended fabric layer 1 is provided with a polyurethane coating 4.

Another difference from the first embodiment is that: an antibacterial fabric layer 5 is compounded between the antistatic fabric layer 2 and the polyester-cotton blended fabric layer 1. The antibacterial fabric layer 5 is formed by interweaving apocynum fiber yarns with silver ions attached to the surfaces. The apocynum fiber has good antibacterial property, has obvious inhibition effect on candida albicans, staphylococcus aureus, escherichia coli, pseudomonas aeruginosa and the like, and combines silver ions attached to the apocynum fiber, thereby further improving the antibacterial capability of the apocynum fiber yarn.

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 (7)

1. An antistatic polyester-cotton blended fabric is characterized by comprising a polyester-cotton blended fabric layer (1); one side of the polyester-cotton blended fabric layer (1) is compounded with an antistatic fabric layer (2), and the other side is compounded with a polyester-nylon fabric layer (3);

the antistatic fabric layer (2) is formed by interweaving polyaniline conductive yarns and silk conductive yarns serving as warp and weft yarns, and the silk conductive yarns comprise degummed silk yarns (21) and PANI/PVA conductive layers (22) coated on the outer sides of the degummed silk yarns.

2. The antistatic polyester-cotton blended fabric according to claim 1, wherein the polyester-cotton blended fabric layer (1) is formed by interweaving polyester-cotton core-spun yarns, and the polyester-cotton core-spun yarns comprise high-strength polyester filaments serving as core yarns and polyester-cotton mixed fiber layers coated on the outer sides of the core yarns.

3. The antistatic polyester-cotton blended fabric according to claim 1, wherein the polyester-nylon fabric layer (3) is formed by interweaving polyester filaments serving as warp yarns and superfine polyester-nylon mixed filaments serving as weft yarns according to weft surface tissues.

4. The antistatic polyester-cotton blended fabric according to claim 1, wherein the antistatic fabric layer (2) is formed by interweaving polyaniline conductive yarns as warp yarns and silk conductive yarns as weft yarns according to a warp surface texture, and one side of the warp surface is close to one side of the polyester-cotton blended fabric layer (1).

5. An antistatic polyester-cotton blended fabric according to claim 1, characterized in that a polyurethane coating (4) is arranged on one side of the polyester-nylon fabric layer (3) far away from the polyester-cotton blended fabric layer (1).

6. An antistatic polyester-cotton blended fabric according to any one of claims 1 to 5, wherein an antibacterial fabric layer (5) is compounded between the antistatic fabric layer (2) and the polyester-cotton blended fabric layer (1).

7. The antistatic polyester-cotton blended fabric according to claim 6, wherein the antibacterial fabric layer (5) is formed by interweaving apocynum fiber yarns with silver ions attached to the surfaces.