CN220639167U - High-elastic flame-retardant polyester dyed fabric - Google Patents

Abstract

The utility model discloses a high-elastic flame-retardant polyester dyed fabric, which relates to the technical field of polyester, and aims at solving the problems that the high-elastic flame-retardant polyester dyed fabric has no flame-retardant effect, is easy to burn when a fabric is in contact with sparks or high temperature, has low safety and is easy to generate static electricity, so that when a human body is in a static state for a long time, the human body is unfavorable, and the wearing comfort is poor. The utility model can effectively improve the flame retardant effect of the terylene dyed cloth, further improve the elasticity, the wear resistance, the antibacterial effect and the bacteriostatic effect of the terylene dyed cloth, effectively prevent the human body from being in an electrostatic state for a long time, be beneficial to the health of the human body and improve the wearing comfort.

Description

High-elastic flame-retardant polyester dyed fabric

Technical Field

The utility model relates to the technical field of terylene, in particular to high-elasticity flame-retardant terylene dyed cloth.

Background

Polyester, namely polyester fiber, is a synthetic fiber made of organic dibasic acid and dihydric alcohol through chemical polycondensation, belongs to one of high molecular compounds, has excellent wrinkle resistance and shape retention, the manufactured clothes are not easy to wrinkle in the wearing process, can keep the original shape of the clothes, and secondly, the polyester fiber has very high strength and elastic recovery capability, so that the woven fabric is firm and durable, and can be quickly recovered, and in addition, the polyester fiber also has the characteristics of abrasion resistance, non-sticking and the like, so that the fabric looks tidier.

However, the polyester dyed cloth sold in the market has the following problems when actually worn:

1. the flame-retardant fabric has no flame-retardant effect, is easy to burn when the fabric encounters sparks or high temperature, and has low safety;

2. when the garment is worn, static electricity is easy to generate, so that the garment is unfavorable to a human body and has poor wearing comfort when the human body is in a static state for a long time.

Disclosure of Invention

The utility model provides high-elastic flame-retardant terylene dyed fabric, which solves the problems that terylene in the market does not have flame-retardant effect, the fabric is easy to burn when meeting a spark or high temperature, the safety is low, static electricity is easy to generate, and when a human body is in a static state for a long time, the fabric is unfavorable to the human body and the wearing comfort is poor.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the utility model provides a fire-retardant dacron dyeing cloth of high bullet, includes the surface fabric basic unit, the seam has the conducting layer on the surface fabric basic unit top outer wall, and the seam has fire-retardant wearing layer on the conducting layer top outer wall, the seam has antistatic backing on the surface fabric basic unit bottom outer wall, and the seam has the surface fabric inside lining on the antistatic backing bottom outer wall.

Preferably, the fabric base layer comprises polyester yarns, and the polyester yarns are mutually woven.

Preferably, the conductive layer includes a first spandex yarn and a conductive fiber yarn, and the first spandex yarn and the conductive fiber yarn are warp-knitted with each other.

Through the scheme, static electricity generated by the fabric base layer is guided into the outside air through the conductive fiber yarns, and the elasticity of the fabric base layer is further improved by utilizing the elastic performance of the first spandex yarns.

Preferably, the flame-retardant wear-resistant layer comprises composite yarns, the composite yarns are woven from warps and wefts, the composite yarns comprise nylon yarns, flame-retardant viscose yarns and first XLA fiber yarns, and the nylon yarns, the flame-retardant viscose yarns and the first XLA fiber yarns are twisted with each other.

Through the scheme, the wear-resistant effect of the outer layer of the fabric is improved through the nylon yarns, the outer layer of the fabric has a flame-retardant effect through the flame-retardant viscose fibers, and the elasticity of the wear-resistant layer is improved through the first XLA fiber yarns.

Preferably, the antistatic layer comprises an antistatic polypropylene and a second spandex yarn, and the antistatic polypropylene and the second spandex yarn are mutually warp knitted.

Through the scheme, the static electricity generated by mutual friction between the fabric and a human body is reduced through the antistatic polypropylene, and the elasticity of the antistatic polypropylene is improved through the second polyurethane yarns.

Preferably, the lining comprises an antibacterial composite yarn and a flame-retardant composite yarn, the antibacterial composite yarn and the flame-retardant composite yarn are mutually warp-weft knitted, the antibacterial composite yarn comprises a bamboo charcoal fiber yarn and a second XLA fiber yarn, the bamboo charcoal fiber yarn and the second XLA fiber yarn are mutually twisted, the flame-retardant composite yarn comprises an polysulfonamide yarn and a third XLA fiber yarn, and the polysulfonamide yarn and the third XLA fiber yarn are mutually twisted.

Through the scheme, the antibacterial and bacteriostatic effects of the fabric lining are improved through the bamboo charcoal fiber yarns, bacteria are prevented from breeding, the flame retardant effects of the fabric lining are improved through the polysulfonamide fiber yarns, and the elasticity of the fabric lining is improved through the second XLA fiber yarns and the third XLA fiber yarns.

The beneficial effects of the utility model are as follows:

1. be provided with fire-retardant wearing layer and fabric inside lining, improve the outer wear-resisting effect of surface fabric through the nylon yarn, fire-retardant viscose fiber makes the surface fabric outer have flame retardant effect, first XLA fiber yarn improves the elasticity of wearing layer, improve the antibacterial effect of surface fabric inside lining through bamboo charcoal fiber yarn, prevent the bacterium from breeding, polysulfonamide fiber yarn improves the flame retardant effect of surface fabric inside lining, second XLA fiber yarn and third XLA fiber yarn improve the elasticity of surface fabric inside lining, can effectively improve the flame retardant effect of dacron dyeing cloth, and further improve elasticity, wearability and the antibacterial effect of dacron dyeing cloth.

2. The anti-static fabric comprises a fabric base layer, wherein the fabric base layer is formed by conducting fiber yarns, the static electricity generated by the fabric base layer is led to the outside air through the conducting fiber yarns, the elasticity of the fabric base layer is further improved by utilizing the elastic performance of the first spandex yarns, the static electricity generated by mutual friction between the fabric and a human body is reduced through the anti-static polypropylene, the elasticity of the anti-static polypropylene is improved by the second spandex yarns, the human body can be effectively prevented from being in a static state for a long time, the health of the human body is facilitated, and the wearing comfort is improved.

In conclusion, the flame-retardant effect of the polyester dyed fabric can be effectively improved, the elasticity, the wear resistance and the antibacterial and bacteriostatic effects of the polyester dyed fabric are further improved, the human body can be effectively prevented from being in an electrostatic state for a long time, the human body health is facilitated, and the wearing comfort is improved.

Drawings

Fig. 1 is a schematic diagram of a front view cross-section structure of a high-elastic flame-retardant polyester dyed fabric.

Fig. 2 is a schematic diagram of a conductive layer textile structure of a high-elastic flame-retardant polyester dyed fabric.

Fig. 3 is a schematic diagram of a flame-retardant and wear-resistant layer textile structure of a high-elastic flame-retardant polyester dyed fabric.

Fig. 4 is a schematic diagram of a composite yarn structure of a high-elastic flame-retardant polyester dyed fabric according to the present utility model.

Fig. 5 is a schematic diagram of an antistatic layer textile structure of a high-elastic flame-retardant polyester dyed fabric.

Fig. 6 is a schematic diagram of a fabric lining textile structure of the high-elastic flame-retardant terylene dyed fabric.

Fig. 7 is a schematic diagram of an antibacterial composite yarn structure of a high-elastic flame-retardant polyester dyed fabric.

Fig. 8 is a schematic diagram of a flame-retardant composite yarn structure of a high-elastic flame-retardant polyester dyed fabric according to the present utility model.

In the figure: 1. a fabric base layer; 2. a conductive layer; 201. a first spandex yarn; 202. a conductive fiber yarn; 3. a flame retardant wear resistant layer; 31. a composite yarn; 311. nylon yarn; 312. flame retardant viscose yarns; 313. a first XLA fiber yarn; 4. an antistatic layer; 401. antistatic polypropylene; 402. a second spandex yarn; 5. lining a fabric; 51. an antimicrobial composite yarn; 511. bamboo charcoal fiber yarns; 512. a second XLA fiber yarn; 52. flame retardant composite yarn; 521. polysulfonamide yarns; 522. and a third XLA fiber yarn.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

1, referring to fig. 1-8, a high-elastic flame-retardant polyester dyed fabric comprises a fabric base layer 1 formed by mutually weaving polyester yarns, a conductive layer 2 is sewn on the outer wall of the top of the fabric base layer 1, the conductive layer 2 comprises a first spandex yarn 201 and a conductive fiber yarn 202, the first spandex yarn 201 and the conductive fiber yarn 202 are mutually warp-knitted, a flame-retardant wear-resistant layer 3 is sewn on the outer wall of the top of the conductive layer 2, the flame-retardant wear-resistant layer 3 comprises a composite yarn 31, the composite yarn 31 is mutually warp-weft-knitted, the composite yarn 31 comprises a nylon yarn 311, a flame-retardant viscose fiber yarn 312 and a first XLA fiber yarn 313, the nylon yarn 311, the flame-retardant viscose fiber yarn 312 and the first XLA fiber yarn 313 are mutually twisted, an antistatic layer 4 is sewn on the outer wall of the bottom of the fabric base layer 1, the antistatic layer 4 comprises an antistatic polypropylene yarn 401 and a second spandex yarn 402, the antistatic polypropylene yarn 401 and the second spandex yarn 402 are mutually warp-knitted, a flame-retardant wear-resistant layer 5 is sewn on the outer wall of the bottom of the antistatic layer 4, the composite yarn comprises a flame-retardant yarn 51 and a composite yarn 512, the composite yarn and a flame-retardant yarn 512 is mutually twisted with an XLA yarn 512, the composite yarn 52 and an XLA yarn 512 is formed by mutually twisted with a yarn 512, and a composite yarn of an antibacterial yarn 512 is formed by mutually twisting an antibacterial yarn and a yarn 512, and an XLA composite yarn is formed by mutually yarn and a composite yarn 52 and a yarn 512.

Working principle: the outer wear-resisting effect of the fabric is improved through the nylon yarns 311, the flame-retardant viscose fibers 312 enable the outer layer of the fabric to have the flame-retardant effect, the first XLA fiber yarns 313 improve the elasticity of the wear-resisting layer, the antibacterial and bacteriostatic effects of the fabric lining 5 are improved through the bamboo charcoal fiber yarns 511, bacteria are prevented from breeding, the flame-retardant effect of the fabric lining is improved through the polysulfonamide yarns 521, the elasticity of the fabric lining 5 is improved through the second XLA fiber yarns 512 and the third XLA fiber yarns 522, static electricity generated by the fabric base layer is guided into the outside air through the conductive fiber yarns 202, the elasticity of the fabric base layer 1 is further improved by utilizing the elastic performance of the first spandex yarns 201, the static electricity generated by mutual friction between the fabric and a human body is reduced through the antistatic polypropylene yarns 401, and the elasticity of the antistatic polypropylene 401 is improved through the second spandex yarns 402.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (6)

1. The utility model provides a fire-retardant dacron dyeing cloth of high bullet, includes surface fabric basic unit (1), its characterized in that, the seam has conducting layer (2) on surface fabric basic unit (1) top outer wall, and the seam has fire-retardant wearing layer (3) on conducting layer (2) top outer wall, the seam has antistatic backing (4) on surface fabric basic unit (1) bottom outer wall, and the seam has surface fabric inside lining (5) on antistatic backing (4) bottom outer wall.

2. The high-elastic flame-retardant polyester dyed fabric according to claim 1, characterized in that the fabric base layer (1) comprises polyester yarns, and the polyester yarns are woven with each other.

3. The high-elastic flame-retardant polyester dyed fabric according to claim 1, characterized in that the conductive layer (2) comprises a first spandex yarn (201) and a conductive fiber yarn (202), and the first spandex yarn (201) and the conductive fiber yarn (202) are warp-knitted with each other.

4. The high-elastic flame-retardant polyester dyed fabric according to claim 1, wherein the flame-retardant wear-resistant layer (3) comprises a composite yarn (31), the composite yarn (31) is woven with each other in warp and weft, the composite yarn (31) comprises a nylon yarn (311), a flame-retardant viscose fiber yarn (312) and a first XLA fiber yarn (313), and the nylon yarn (311), the flame-retardant viscose fiber yarn (312) and the first XLA fiber yarn (313) are twisted with each other.

5. The high-elastic flame-retardant polyester dyed fabric according to claim 1, wherein the antistatic layer (4) comprises an antistatic polypropylene (401) and a second spandex yarn (402), and the antistatic polypropylene (401) and the second spandex yarn (402) are warp-knitted with each other.

6. The high-elastic flame-retardant polyester dyed fabric according to claim 1, wherein the fabric lining (5) comprises an antibacterial composite yarn (51) and a flame-retardant composite yarn (52), the antibacterial composite yarn (51) and the flame-retardant composite yarn (52) are woven with each other in warp and weft, the antibacterial composite yarn (51) comprises a bamboo charcoal fiber yarn (511) and a second XLA fiber yarn (512), the bamboo charcoal fiber yarn (511) and the second XLA fiber yarn (512) are twisted with each other, the flame-retardant composite yarn (52) comprises an polysulfonamide yarn (521) and a third XLA fiber yarn (522), and the polysulfonamide yarn (521) and the third XLA fiber yarn (522) are twisted with each other.