CN111136964A

CN111136964A - Electromagnetic radiation resistant cashmere product and processing method thereof

Info

Publication number: CN111136964A
Application number: CN201911389205.2A
Authority: CN
Inventors: 王松杰
Original assignee: Qianshan Jincheng Yongtai Garment Co ltd
Current assignee: Qianshan Jincheng Yongtai Garment Co ltd
Priority date: 2019-12-30
Filing date: 2019-12-30
Publication date: 2020-05-12

Abstract

The invention discloses an electromagnetic radiation resistant cashmere product and a processing method thereof, and belongs to the technical field of functional textiles. The cashmere product body is sequentially provided with a stain-resistant layer, an outer layer, a tensile layer and an inner layer from outside to inside, wherein the tensile layer is formed by crosswise weaving warps and wefts. The cashmere product has the hand feeling, texture and appearance of a common cashmere product, the anti-electromagnetic radiation filament yarns in the shielding layer are in close contact with each other, the shielding effect formed by a conductive loop is fully exerted, the high-efficiency anti-electromagnetic shielding effect is achieved, the tensile layer formed by cross weaving of the nylon filament yarns and the Richcel fibers is arranged between the outer layer and the inner layer, the mechanical strength of the nylon filament yarns is high, the tensile strength of the outer layer is improved, the nylon filament yarns are resistant to friction, the service life of the cashmere product is greatly prolonged, the size stability of cloth is improved by the Richcel fibers, and the problem that the cloth cannot shrink back to the original shape after being stretched is solved.

Description

Electromagnetic radiation resistant cashmere product and processing method thereof

Technical Field

The invention belongs to the technical field of functional textiles, and particularly relates to an electromagnetic radiation resistant cashmere product and a processing method thereof.

Background

When a human body is in a non-ionizing radiation electromagnetic field for a long time, the bioelectricity effect and the heat effect can generate harmful effects on the nervous system, the circulatory system, the endocrine system, the reproductive system and other systems of the human body, so that symptoms such as fatigue, insomnia, dysphoria, anxiety, alopecia and the like are generated, even serious consequences such as increase of white blood cells, infertility, fetal deformity and the like are generated, and along with the increasing and popularization of electronic products, the protection on electromagnetic radiation has attracted great attention of people.

There are three main categories of current anti-electromagnetic radiation fabrics. Most of anti-electromagnetic radiation fabrics are blended yarn by stainless steel wires and cotton or polyester-cotton fibers, and then woven stainless steel and cotton or polyester-cotton fiber blended products are obtained through a weaving process. The content of stainless steel fiber in the product is generally 10-25%, and the electromagnetic radiation resistance is generally 10-25 db. Because the stainless steel fiber and the cotton or the polyester-cotton fiber are blended, the stainless steel fiber can not be effectively contacted, the fabric with high shielding efficiency is difficult to achieve, the hand feeling of the fabric is hard along with the increase of the content of the stainless steel fiber, the phenomenon that the stainless steel fiber emerges from the cloth cover exists, and the hand feeling and the appearance are limited. Another type of fabric for preventing electromagnetic radiation is to endow the fabric with the function of preventing electromagnetic radiation by means of fabric surface metallization, and the fabric for preventing electromagnetic radiation is formed by coating metal on synthetic fiber fabric by physical (vacuum evaporation, vacuum ion plating or sputtering), chemical (electroplating or chemical plating) or combination of the two methods. The main metallized fabrics at present are acrylic fibers, polyester fibers or nylon fibers with copper, nickel and alloys coated on the surfaces. The fabric metalized product has the problems that the color is single, the bonding force between the metal layer and the synthetic fiber is insufficient, the metal layer and the synthetic fiber fall off, the use durability of the fabric metalized product is influenced, the hand feeling of the fabric is hard and the like in the wearing process. The third type of anti-electromagnetic radiation fabric adopts a manner of embedding and weaving common yarns and metal conductive yarns or synthetic fiber metalized conductive yarns, and the common yarns influence the effective contact of the conductive yarns to influence the formation of a conductive loop, so that the conductivity of the conductive fibers cannot be fully utilized, and the anti-electromagnetic radiation efficiency of the fabric is low. And the inherent color of the conductive yarn can affect the appearance of the anti-electromagnetic radiation fabric.

Disclosure of Invention

The invention aims to provide an electromagnetic radiation resistant cashmere product and a processing method thereof, so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: the cashmere product body is sequentially provided with a stain-resistant layer, an outer layer, a tensile layer and an inner layer from outside to inside, and the tensile layer is formed by cross weaving of warps and wefts.

Further, the outer layer is formed by knitting cashmere yarns, and the inner layer is formed by knitting spandex filament covering yarns with silver wrapped on the surface.

Further, the warp yarns are made of a nylon filament material, and the weft yarns are made of a Richcel fiber material.

Further, the stain-resistant layer is made of a nanofiber cloth material, and the thickness of the stain-resistant layer is 0.7-1.2 mm.

Furthermore, the stain resistant layer, the outer layer, the tensile layer and the inner layer are connected in a hot-pressing attaching mode or a sewing mode.

Further, the denier of the multifilament of the warp yarn and the weft yarn is 20-25d, and the fineness of the monofilament is 1.5-2 dfp.

Further, the cashmere product body can be a knitted product or a woven product.

Further, the processing method of the knitted product comprises the following steps:

the method comprises the following steps: selecting clean nanofiber cloth with proper thickness for later use;

step two: knitting cashmere yarns into cashmere knitted fabrics, knitting spandex filament core-spun yarns with silver wrapped on the surface into anti-electromagnetic radiation filament yarn knitted fabrics, and knitting polyamide filaments and Richcel fibers into tensile fiber knitted fabrics in a crossed manner;

step three: cutting the nanofiber cloth, the cashmere knitted fabric, the electromagnetic radiation resistant filament yarn knitted fabric and the tensile fiber knitted fabric according to the plate types of the electromagnetic radiation resistant cashmere knitted product respectively so as to ensure that the nanofiber cloth, the cashmere knitted fabric, the electromagnetic radiation resistant filament yarn knitted fabric and the tensile fiber knitted fabric are consistent in size and size;

step four: and sewing the disc button sewing machine into four layers of electromagnetic radiation resistant cashmere knitted products.

Further, the processing method of the woven product comprises the following steps:

step two: respectively weaving cashmere woven fabric and anti-electromagnetic radiation filament yarn woven fabric by adopting conventional cashmere blended yarns and spandex filament core-spun yarns with silver wrapped on the surfaces;

step two: the nylon filament and the Richcel fiber are crossly woven into the tensile fiber woven fabric;

step four: respectively cutting the nanofiber cloth, the cashmere knitted fabric, the anti-electromagnetic radiation filament yarn knitted fabric and the tensile fiber knitted fabric according to the plate type of the anti-electromagnetic radiation cashmere knitted product;

step five: and (3) the hot-pressing laminating of the four woven fabrics is realized by using a water-based adhesive hot-pressing compound machine and PU adhesive to process into the electromagnetic radiation resistant cashmere knitted product.

Compared with the prior art, the invention has the beneficial effects that:

1. the electromagnetic radiation resistant cashmere product has the hand feeling, texture and appearance of common cashmere products, the electromagnetic radiation resistant filament yarns in the shielding layer are in close contact with each other, the shielding effect formed by the conductive loop is fully exerted, and the electromagnetic radiation resistant cashmere product has an efficient electromagnetic shielding effect.

2. According to the anti-electromagnetic radiation cashmere product, the tensile layer formed by cross weaving of the nylon filament and the Richcel fiber is arranged between the outer layer and the inner layer, the nylon filament is high in mechanical strength, the tensile strength of the outer layer is improved, the nylon filament is resistant to friction, the service life of the cashmere product is greatly prolonged, the Richcel fiber improves the size stability of cloth, and the problem that the cloth cannot shrink back to the original shape after being stretched is solved.

3. According to the electromagnetic radiation resistant cashmere product, the stain resistant layer made of the nanofiber cloth is arranged on the outer side of the outer layer, so that stain resistant and anti-staining effects such as oil stain resistance of the electromagnetic radiation resistant cashmere product can be effectively improved, the cleaning times of the electromagnetic radiation resistant cashmere product in the use period are reduced, and the wearing convenience of users is improved.

Drawings

Fig. 1 is a schematic view of the overall structure of an electromagnetic radiation resistant cashmere product of the present invention.

Fig. 2 is a schematic cross-sectional structure diagram of an electromagnetic radiation resistant cashmere product of the present invention.

Fig. 3 is a schematic structural view of a tensile layer of an electromagnetic radiation resistant cashmere product of the present invention.

In the figure: 1. a cashmere product body; 2. a stain resistant layer; 3. an outer layer; 4. a tensile layer; 5. an inner layer; 6. warp yarns; 7. and (4) weft yarns.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

As shown in fig. 1-3, an electromagnetic radiation resistant cashmere product comprises a cashmere product body 1, wherein the cashmere product body 1 is sequentially provided with a stain resistant layer 2, an outer layer 3, a tensile layer 4 and an inner layer 5 from outside to inside, and the tensile layer 4 is formed by cross weaving of warp yarns 6 and weft yarns 7.

The outer layer 3 is formed by knitting cashmere yarns, and the inner layer 5 is formed by knitting spandex filament covering yarns with silver wrapped on the surface.

Wherein the warp yarns 6 are made of a nylon filament material, and the weft yarns 7 are made of a Richcel fiber material.

Wherein, the stain resistant layer 2 is made of nano fiber cloth material, and the thickness of the stain resistant layer 2 is 0.7-1.2 mm.

Wherein, adopt hot pressing laminating mode or sewing up the mode to connect between resistant dirty layer 2, outer 3, tensile layer 4 and the inlayer 5.

Wherein the multifilament denier of the warp yarn 6 and the weft yarn 7 is 20-25d, and the monofilament fineness is 1.5-2 dfp.

Wherein, the cashmere product body 1 can be a knitted product or a woven product.

The processing method of the knitted product comprises the following steps:

Example 2

Wherein, the processing method of the woven product comprises the following steps:

The working principle and the using process of the invention are as follows: the cashmere product body 1 can be divided into two cashmere products, namely a knitted product and a woven product; the method for processing the knitted product comprises the following steps: the method comprises the following steps: selecting clean nanofiber cloth with proper thickness for later use; step two: knitting cashmere yarns into cashmere knitted fabrics, knitting spandex filament core-spun yarns with silver wrapped on the surface into anti-electromagnetic radiation filament yarn knitted fabrics, and knitting polyamide filaments and Richcel fibers into tensile fiber knitted fabrics in a crossed manner; step three: cutting the nanofiber cloth, the cashmere knitted fabric, the electromagnetic radiation resistant filament yarn knitted fabric and the tensile fiber knitted fabric according to the plate types of the electromagnetic radiation resistant cashmere knitted product respectively so as to ensure that the nanofiber cloth, the cashmere knitted fabric, the electromagnetic radiation resistant filament yarn knitted fabric and the tensile fiber knitted fabric are consistent in size and size; step four: sewing the disc button sewing machine into four layers of electromagnetic radiation resistant cashmere knitted products; a method of processing a woven article comprising the steps of: the method comprises the following steps: selecting clean nanofiber cloth with proper thickness for later use; step two: respectively weaving cashmere woven fabric and anti-electromagnetic radiation filament yarn woven fabric by adopting conventional cashmere blended yarns and spandex filament core-spun yarns with silver wrapped on the surfaces; step two: the nylon filament and the Richcel fiber are crossly woven into the tensile fiber woven fabric; step four: respectively cutting the nanofiber cloth, the cashmere knitted fabric, the anti-electromagnetic radiation filament yarn knitted fabric and the tensile fiber knitted fabric according to the plate type of the anti-electromagnetic radiation cashmere knitted product; step five: and (3) the hot-pressing laminating of the four woven fabrics is realized by using a water-based adhesive hot-pressing compound machine and PU adhesive to process into the electromagnetic radiation resistant cashmere knitted product.

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

Claims

1. The utility model provides an anti electromagnetic radiation cashmere goods, includes cashmere goods body (1), its characterized in that: the cashmere product body (1) is sequentially provided with a stain-resistant layer (2), an outer layer (3), a tensile layer (4) and an inner layer (5) from outside to inside, and the tensile layer (4) is formed by alternately weaving warp yarns (6) and weft yarns (7).

2. The electromagnetic radiation resistant cashmere product of claim 1, wherein: the outer layer (3) is formed by knitting cashmere yarns, and the inner layer (5) is formed by knitting spandex filament core-spun yarns with silver wrapped on the surface.

3. The electromagnetic radiation resistant cashmere product of claim 1, wherein: the warp yarns (6) are made of nylon filament materials, and the weft yarns (7) are made of Richcel fiber materials.

4. The electromagnetic radiation resistant cashmere product of claim 1, wherein: the stain-resistant layer (2) is made of nano-fiber cloth materials, and the thickness of the stain-resistant layer (2) is 0.7-1.2 mm.

5. The electromagnetic radiation resistant cashmere product of claim 1, wherein: the stain-resistant layer (2), the outer layer (3), the tensile layer (4) and the inner layer (5) are connected by a hot-pressing attaching mode or a sewing mode.

6. The electromagnetic radiation resistant cashmere product of claim 3, wherein: the multifilament denier of the warp yarn (6) and the weft yarn (7) is 20-25d, and the monofilament fineness is 1.5-2 dfp.

7. The electromagnetic radiation resistant cashmere product of claims 1 to 6, wherein: the cashmere product body (1) can be a knitted product or a woven product.

8. The electromagnetic radiation resistant cashmere product of claim 7, wherein: the processing method of the knitted product comprises the following steps:

9. The electromagnetic radiation resistant cashmere product of claim 7, wherein: the processing method of the woven product comprises the following steps: