CN214491952U - Double-layer flame-retardant anti-static polyester fabric - Google Patents

Abstract

The utility model discloses a double-layer flame-retardant antistatic terylene fabric, which comprises an antistatic outer layer fabric and an antibacterial inner layer fabric which are arranged from outside to inside in sequence; the anti-static outer layer fabric and the bacteriostatic inner layer fabric are respectively provided with a buckling seat and a buckling nail which are matched with each other; the anti-static outer layer fabric and the bacteriostatic inner layer fabric are buckled with each other; a flame-retardant protective layer is embedded between the anti-static outer layer fabric and the bacteriostatic inner layer fabric; the anti-static outer layer fabric is formed by alternately interweaving conductive fibers and polyester filaments; the surface of the anti-static outer layer fabric is coated with a high-temperature-resistant coating, cylindrical bulges are arrayed in the anti-static outer layer fabric, and a metal sensing net and a temperature sensor are arranged in the bulges; an elastic area, a reinforcing area, a flame-retardant area and a refrigerating area are sequentially arranged in the flame-retardant protective layer. The flame-retardant antistatic fabric has the advantages that the structure of the fabric is rich in layers, the texture is thick, the flame-retardant and antistatic performances of the fabric are good, and the application range is wider.

Description

Double-layer flame-retardant anti-static polyester fabric

Technical Field

The utility model relates to a textile fabric, concretely relates to double-deck fire-retardant antistatic polyester fabric.

Background

With the increasing living standard, the functional requirements on the clothes are higher and higher. In some special industries, the requirements on the flame retardant property of the clothes are required, the clothes are not only the requirements on outerwear, but are better protected from outside to inside, and the existing market lacks a flame retardant fabric which is comfortable to wear and good in fabric elastic effect and shaping effect.

The flame-retardant fabric in the prior art is mostly woven by adopting flame-retardant yarns, but the flame-retardant fabric woven by adopting the flame-retardant yarns has the disadvantages of high production cost, complex process, poor flame-retardant effect, light and thin fabric, and electric sparks generated by static electricity in an environment with many dust particles, thus threatening the health of human bodies.

Therefore, a new double-layer flame-retardant antistatic polyester fabric needs to be designed.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide a double-deck fire-retardant antistatic polyester fabric, it can make the structure level of surface fabric abundant, and the texture is thick and solid, and the fire-retardant and antistatic properties of surface fabric are good, and application scope is wider.

In order to solve the technical problem, the utility model provides a double-layer flame-retardant antistatic terylene fabric, which comprises an antistatic outer layer fabric and an antibacterial inner layer fabric which are arranged in sequence from outside to inside; the anti-static outer layer fabric and the bacteriostatic inner layer fabric are respectively provided with a buckling seat and a buckling nail which are matched with each other; the anti-static outer layer fabric and the bacteriostatic inner layer fabric are buckled with each other; a flame-retardant protective layer is embedded between the anti-static outer layer fabric and the bacteriostatic inner layer fabric; the anti-static outer layer fabric is formed by alternately interweaving conductive fibers and polyester filaments; the surface of the anti-static outer layer fabric is coated with a high-temperature-resistant coating, cylindrical bulges are uniformly arrayed in the anti-static outer layer fabric, and a metal sensing net and a temperature sensor for detecting the external temperature are arranged in the bulges; an elastic area, a reinforcing area, a flame-retardant area and a refrigerating area are sequentially arranged in the flame-retardant protective layer.

Preferably, a partition board is uniformly bonded in the elastic zone, an elastic cushion body is bonded at the bottom of the partition board and is arranged in a columnar shape, and nylon low-elasticity threads are wound on the elastic cushion body.

Preferably, the reinforcing area is filled with supporting fibers, the supporting fibers are arranged in a strip shape, and two ends of the supporting fibers are symmetrically provided with bending parts for increasing supporting force.

Preferably, a flame-retardant channel is configured in the flame-retardant zone, and flame-retardant particles with excellent high-temperature resistance and flame retardance are filled in the flame-retardant channel.

Preferably, a smoke sensor for sensing whether a fire occurs outside is fixedly arranged at one end of the flame-retardant channel, and a microprocessor configured with the smoke sensor is arranged at the other end of the flame-retardant channel; the microprocessor is electrically connected with the temperature sensor.

Preferably, a refrigerating piece is arranged in the refrigerating area, and the refrigerating piece is a semiconductor refrigerating piece; the semiconductor refrigerating piece is electrically connected with the microprocessor.

Preferably, a mesh cloth area for ventilation is additionally arranged between the refrigerating area and the flame retardant area, ventilation holes are formed in the mesh cloth area, and the diameter of each ventilation hole is 0.5 mu m.

Preferably, the bacteriostatic inner-layer fabric is formed by alternately weaving second warp yarns and second weft yarns in a floating and sinking manner; a twill jacquard area is arranged on the antibacterial inner-layer fabric; the twill jacquard area is woven by four needle paths, the weaving pattern takes four paths as a circulation, and the four paths of patterns are sequentially arranged; the first path is tuck stitch, looping stitch and tuck stitch in sequence; the second path is sequentially provided with floating lines, looping tissues and tucking tissues; the third path is a looping tissue, a tucking tissue and a tucking tissue in sequence; the fourth path is sequentially a floating thread, a tuck stitch, a looping stitch and a floating thread.

Preferably, the fineness of the second warp yarn is 56dtex, and the fineness of the second weft yarn is 58 dtex.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model has the advantages that the anti-static outer layer fabric and the bacteriostatic inner layer fabric are arranged, so that the fabric not only has anti-static performance but also has bacteriostatic performance; the anti-static outer layer fabric and the bacteriostatic inner layer fabric are mutually buckled and arranged, can be buckled and disassembled, are quick and convenient to use, and are embedded with the flame-retardant protective layer; the flame-retardant fabric has good flame-retardant performance, is rich in structural hierarchy, and is more enhanced in heat retention.

2. The utility model discloses an anti-static outer surface fabric is formed by conductive fiber and dacron filament in turn, and it can possess certain antistatic performance, also can not produce static easily under the more condition of dust granule, can not take place electric spark or explosion.

3. The utility model discloses a set gradually elastic region, reinforcing district, fire-retardant district and refrigeration district in the fire-retardant protective layer, can make the function of surface fabric abundanter practical, the application scope of surface fabric is wider.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings required to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the internal structure of a flame retardant protective layer;

FIG. 3 is a schematic diagram of a weaving structure of the bacteriostatic inner-layer fabric;

FIG. 4 is a schematic view of the pattern weaving of the twill patterning area.

The anti-static smoke-proof fabric comprises 1-an anti-static outer layer fabric, 2-needle holes, 3-bulges, 4-a flame-retardant protective layer, 5-an anti-bacterial inner layer fabric, 201-an elastic area, 202-a reinforcing area, 203-a smoke sensor, 204-a flame-retardant area, 205-a microprocessor, 206-a mesh area, 207-a refrigerating area, 208-a refrigerating sheet, 209-a partition plate, 210-an elastic cushion body, 211-supporting fibers, 212-a flame-retardant channel, 31-second warp yarns, 32-second weft yarns, 41-floating yarns, 42-tuck stitches and 43-loop stitches.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments obtained by a person skilled in the art without any inventive work based on the embodiments of the present invention belong to the protection scope of the present invention.

Examples

Referring to fig. 1-4, the utility model discloses a double-deck fire-retardant antistatic polyester fabric, include:

the anti-static outer-layer fabric 1 and the bacteriostatic inner-layer fabric 5 are sequentially arranged from outside to inside.

The anti-static outer layer fabric 1 is provided with the needle holes 2 in a needle punching mode, and the anti-static outer layer fabric 1 can be better in air permeability through the arranged needle holes 2.

Preferably, the antistatic outer layer fabric 1 and the antibacterial inner layer fabric 5 are respectively provided with a buckle seat and a buckle nail which are matched with each other. Through above-mentioned knot seat and pintle, can make above-mentioned antistatic outer surface fabric 1 and the mutual lock setting of antibacterial inlayer surface fabric 5, it can be dismantled according to actual need.

And a flame-retardant protective layer 4 is embedded between the anti-static outer layer fabric 1 and the bacteriostatic inner layer fabric 5.

Through the arrangement of the anti-static outer layer fabric 1 and the antibacterial inner layer fabric 5, the fabric has the anti-static performance and the antibacterial performance. Above-mentioned prevent the mutual lock setting of static outer surface fabric 1 and antibacterial inlayer surface fabric 5, it can the lock dismantle, and the surface fabric is used swiftly convenient, inlays between static outer surface fabric 1 and the antibacterial inlayer surface fabric 5 and is equipped with fire-retardant inoxidizing coating 4. The flame-retardant fabric has good flame-retardant performance, is rich in structural hierarchy, and is more enhanced in heat retention.

The anti-static outer layer fabric 1 is formed by alternately interweaving conductive fibers and polyester filaments. The surface of the anti-static outer shell fabric 1 is coated with a high-temperature-resistant coating, cylindrical bulges 3 are arranged in the anti-static outer shell fabric 1 in an even array mode, the three-dimensional presenting effect of the anti-static outer shell fabric 1 can be better through the bulges 3, and the layers of the shell fabric are richer.

And a metal sensing net and a temperature sensor are arranged in the bulge 3, and can detect the external temperature in real time.

An elastic zone 201, a reinforced zone 202, a flame-retardant zone 204 and a refrigeration zone 207 are sequentially arranged in the flame-retardant protective layer 4.

A partition 209 is uniformly adhered in the elastic region 201, an elastic cushion body 210 is adhered at the bottom of the partition 209, the elastic cushion body 210 is arranged in a columnar shape, and nylon low stretch yarn is wound on the elastic cushion body 210.

The reinforced area 202 is filled with supporting fibers 211, the supporting fibers 211 are arranged in a strip shape, and bending portions for increasing supporting force are symmetrically arranged at two ends of each supporting fiber.

A flame retardant channel 212 is disposed in the flame retardant region 204, and flame retardant particles with excellent high temperature resistance and flame retardancy are filled in the flame retardant channel 212. In a space with higher temperature, the fabric has excellent heat insulation performance and can avoid catching fire.

A smoke sensor 203 is fixedly provided at one end of the flame retardant passage 212. The smoke sensor 203 can sense whether open fire smoke is generated outside. At the other end of the flame retardant channel 212, a microprocessor 205 is provided, which is arranged in connection with the smoke sensor 203, the microprocessor 205 also being electrically connected to a temperature sensor. When the smoke concentration in the air is high or the temperature is high, the smoke sensor 203 and the temperature sensor can perform warning function for the operator even if the data result is detected and transmitted to the microprocessor 205.

A refrigerating plate 208 is disposed in the refrigerating area 207, and the refrigerating plate 208 is a semiconductor refrigerating plate 208. The semiconductor cooling plate 208 is electrically connected to the microprocessor 205. When the temperature is higher, the microprocessor 205 can drive the refrigeration sheet 208 to work, so that the fabric is continuously cooled.

A mesh cloth area 206 is additionally arranged between the refrigeration area 207 and the flame-retardant area 204. The performance of the fabric can be better by arranging the mesh fabric area 206. The mesh cloth area 206 is also provided with air holes, and the diameter of each air hole is 0.5 mu m.

The bacteriostatic inner-layer fabric 5 is formed by alternately weaving second warp yarns 31 and second weft yarns 32 in a floating and sinking manner.

A twill jacquard area is arranged on the antibacterial inner-layer fabric 5; the twill jacquard area is woven by four needle paths, the weaving pattern takes four paths as a circulation, and the four paths of patterns are sequentially arranged; the first path is sequentially tuck tissue 42, looping tissue 43 and tuck tissue 42; the second path is a floating line 41, a looping tissue 43 and a tucking tissue 42 in sequence; the third path is a looping tissue 43, a tucking tissue 42 and a tucking tissue 42 in sequence; the fourth path is a floating thread 41, a tuck stitch 42, a looping stitch 43 and a floating thread 41 in sequence

The titer of the second warp yarns 31 is 56dtex, and the titer of the second weft yarns 32 is 58 dtex. The performance of the woven antibacterial inner layer fabric 5 is better.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (9)

1. The utility model provides a double-deck fire-retardant antistatic polyester fabric which characterized in that includes:

the anti-static outer layer fabric and the bacteriostatic inner layer fabric are sequentially arranged from outside to inside;

the anti-static outer layer fabric and the bacteriostatic inner layer fabric are respectively provided with a buckling seat and a buckling nail which are matched with each other; the anti-static outer layer fabric and the bacteriostatic inner layer fabric are buckled with each other; a flame-retardant protective layer is embedded between the anti-static outer layer fabric and the bacteriostatic inner layer fabric;

needling holes for ventilation are needled on the anti-static outer layer fabric;

the anti-static outer layer fabric is formed by alternately interweaving conductive fibers and polyester filaments; the surface of the anti-static outer layer fabric is coated with a high-temperature-resistant coating, cylindrical bulges are uniformly arrayed in the anti-static outer layer fabric, and a metal sensing net and a temperature sensor for detecting the external temperature are arranged in the bulges;

an elastic area, a reinforcing area, a flame-retardant area and a refrigerating area are sequentially arranged in the flame-retardant protective layer.

2. The double-layer flame-retardant antistatic polyester fabric as claimed in claim 1, wherein the elastic region is uniformly bonded with a partition board, the bottom of the partition board is bonded with an elastic cushion body, the elastic cushion body is arranged in a column shape, and nylon low stretch yarn is wound on the elastic cushion body.

3. The double-layer flame-retardant anti-static polyester fabric according to claim 2, wherein the reinforcing area is filled with supporting fibers, the supporting fibers are arranged in a strip shape, and two ends of the supporting fibers are symmetrically provided with bending portions for increasing supporting force.

4. The double-layer flame-retardant antistatic polyester fabric as claimed in claim 3, wherein a flame-retardant channel is configured in the flame-retardant area, and flame-retardant particles with excellent high-temperature resistance and flame retardance are filled in the flame-retardant channel.

5. The double-layer flame-retardant antistatic polyester fabric as claimed in claim 4, wherein a smoke sensor for sensing whether a fire occurs outside is fixedly arranged at one end of the flame-retardant channel, and a microprocessor configured with the smoke sensor is arranged at the other end of the flame-retardant channel; the microprocessor is electrically connected with the temperature sensor.

6. The double-layer flame-retardant anti-static polyester fabric as claimed in claim 5, wherein a refrigerating sheet is arranged in the refrigerating area, and the refrigerating sheet is a semiconductor refrigerating sheet; the semiconductor refrigerating piece is electrically connected with the microprocessor.

7. The double-layer flame-retardant antistatic polyester fabric as claimed in claim 6, wherein a mesh area for ventilation is additionally arranged between the refrigeration area and the flame-retardant area, ventilation holes are arranged in the mesh area, and the diameter of each ventilation hole is 0.5 μm.

8. The double-layer flame-retardant anti-static polyester fabric as claimed in claim 7, wherein the bacteriostatic inner layer fabric is formed by alternately weaving second warp yarns and second weft yarns in a floating and sinking manner; a twill jacquard area is arranged on the antibacterial inner-layer fabric; the twill jacquard area is woven by four needle paths, the weaving pattern takes four paths as a circulation, and the four paths of patterns are sequentially arranged; the first path is tuck stitch, looping stitch and tuck stitch in sequence; the second path is sequentially provided with floating lines, looping tissues and tucking tissues; the third path is a looping tissue, a tucking tissue and a tucking tissue in sequence; the fourth path is sequentially a floating thread, a tuck stitch, a looping stitch and a floating thread.

9. The double-layer flame-retardant antistatic polyester fabric as claimed in claim 8, wherein the titer of the second warp yarns is 56dtex, and the titer of the second weft yarns is 58 dtex.

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