CN216891416U - High-temperature-resistant and anti-radiation polyester fabric - Google Patents

Abstract

The utility model discloses a high-temperature-resistant and radiation-resistant polyester fabric which comprises a fabric body formed by interweaving warp yarns and weft yarns, wherein the fabric body is formed by interweaving a tying weft tying tissue, the warp yarns on the surface layer are interwoven with the weft yarns on the surface layer to form a surface layer, and the warp yarns on the inner layer are interwoven with the weft yarns on the inner layer to form an inner layer; the surface warp yarns and the surface weft yarns are radiation-proof polyester core-spun yarns, each radiation-proof polyester core-spun yarn comprises a core yarn and a coating layer, the core yarn is radiation-proof polyester yarns, and the coating layer is flame-retardant polyester staple fibers; the inner layer warp yarns and the inner layer weft yarns are made of flame-retardant polyester filaments; the surface coating on top layer has the silica gel layer. The surface layer is formed by interweaving radiation-proof polyester core-spun yarns, so that the surface layer has good radiation-proof capability. And a silica gel layer is coated on one side of the surface layer to improve the high-temperature resistance of the whole fabric. The flame retardant performance of the whole fabric is further improved by adopting the flame retardant polyester filament yarns as the inner layer. The binding weft binding structure ensures that a certain gap is formed between the inner layer and the surface layer to form an air layer, thereby improving the heat insulation capability.

Description

High-temperature-resistant and anti-radiation polyester fabric

Technical Field

The utility model relates to the technical field of textile fabrics, in particular to a high-temperature-resistant and anti-radiation polyester fabric.

Background

The terylene fabric is a very large chemical fiber garment fabric used in daily life. The most important advantage is that the crease resistance and shape retention are good, so it is suitable for making outdoor articles such as coat clothes, various bags and tents. Polyester has a wide range of applications and is used in large quantities to make articles of clothing and industry. The flame-retardant polyester has permanent flame retardance and wide application range, and not only plays a role of irreplaceability in industrial textiles, interior decoration of buildings, interior decoration of vehicles and the like, but also plays a great role in the field of protective clothing. The existing polyester fabric has low high temperature resistance and poor elastic effect, thereby influencing the use comfort of the polyester fabric. But the performance of the existing flame-retardant polyester fabric in the aspect of radiation resistance is poor.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a high-temperature-resistant and radiation-resistant polyester fabric, the surface layer is formed by interweaving radiation-resistant polyester core-spun yarns, so that the fabric has good radiation resistance, and the coated silica gel layer has good high-temperature resistance. Certain gaps are formed between the surface layer and the inner layer, so that the heat insulation performance of the fabric can be improved.

In order to solve the technical problem, the utility model aims to realize that:

the utility model relates to a high-temperature-resistant and radiation-resistant polyester fabric which comprises a fabric body formed by interweaving warp yarns and weft yarns, wherein the fabric body is formed by interweaving a binding weft binding tissue, the warp yarns comprise surface layer warp yarns and inner layer warp yarns, and the weft yarns comprise surface layer weft yarns, inner layer weft yarns and binding weft yarns; the surface layer warp yarns and the surface layer weft yarns are interwoven to form a surface layer, the inner layer warp yarns and the inner layer weft yarns are interwoven to form an inner layer, and the surface layer and the inner layer are fixedly connected by binding weft yarns;

the surface warp yarns and the surface weft yarns are radiation-proof polyester core-spun yarns, each radiation-proof polyester core-spun yarn comprises a core yarn and a coating layer, the core yarn is radiation-proof polyester yarns, and the coating layer is flame-retardant polyester staple fibers; the inner layer warp yarns and the inner layer weft yarns are flame-retardant polyester filaments;

the surface of the surface layer is coated with a silica gel layer.

On the basis of the above scheme and as a preferable scheme of the scheme: the radiation-proof polyester yarn comprises a first elastic polyester yarn, a far infrared fiber yarn, a second elastic polyester yarn, a nano silver fiber yarn, a third elastic polyester yarn and a metal yarn, wherein the far infrared fiber yarn is spirally wound on one side of the first elastic polyester yarn, the second elastic polyester yarn is spirally wound on one side of the far infrared fiber yarn, the nano silver fiber yarn is spirally wound on one side of the second elastic polyester yarn, the third elastic polyester yarn is spirally wound on one side of the nano silver fiber yarn, and the metal yarn is spirally wound on one side of the third elastic polyester yarn; and the outer surfaces of the first elastic polyester yarns, the far infrared fiber yarns, the second elastic polyester yarns, the nano silver fiber yarns, the third elastic polyester yarns and the metal wires are coated with radiation-proof layers.

On the basis of the above scheme and as a preferable scheme of the scheme: the surface layer warp yarns comprise surface layer first warp yarns, surface layer second warp yarns, surface layer third warp yarns and surface layer fourth warp yarns, and the surface layer weft yarns comprise surface layer first weft yarns, surface layer second weft yarns, surface layer third weft yarns and surface layer fourth weft yarns; the inner layer warp yarns comprise inner layer first warp yarns, inner layer second warp yarns, inner layer third warp yarns and inner layer fourth warp yarns, the inner layer weft yarns comprise inner layer first weft yarns, inner layer second weft yarns, inner layer third weft yarns and inner layer fourth weft yarns, and the binding weft yarns comprise binding first weft yarns, binding second weft yarns, binding third weft yarns and binding fourth weft yarns;

the arrangement rule of the warp yarns is as follows: the surface layer first warp yarns, the inner layer first warp yarns, the surface layer second warp yarns, the inner layer second warp yarns, the surface layer third warp yarns, the inner layer third warp yarns, the surface layer fourth warp yarns and the inner layer fourth warp yarns; the arrangement rule of the weft yarns is as follows: the weft yarn comprises a surface layer first weft yarn, an inner layer first weft yarn, a binding first weft yarn, a surface layer second weft yarn, an inner layer second weft yarn, a binding second weft yarn, a surface layer third weft yarn, an inner layer third weft yarn, a binding third weft yarn, a surface layer fourth weft yarn, an inner layer fourth weft yarn and a binding fourth weft yarn.

On the basis of the above scheme and as a preferable scheme of the scheme: based on warp yarns, the sinking and floating rule of the first weft yarns on the surface layer is as follows: sinking, floating, sinking and floating; the sinking and floating rule of the first weft yarn of the inner layer is as follows: sinking-floating-sinking; the sinking and floating law of the binding first weft yarns is as follows: sinking, floating, sinking and sinking; the sinking and floating rule of the second weft yarns on the surface layer is as follows: sinking-floating; the sinking and floating rule of the second weft yarns of the inner layer is as follows: sinking-floating-sinking; the sinking and floating law of the binding second weft yarns: sinking, floating; the sinking and floating rule of the third weft yarns on the surface layer is as follows: floating-sinking-floating; the sinking and floating rule of the third weft yarns of the inner layer is as follows: sinking, sinking and floating; the sinking and floating rule of the binding third weft yarns is as follows: floating-sinking-floating; the sinking and floating rule of the fourth weft yarn on the surface layer is as follows: floating-sinking-floating; the sinking and floating rule of the fourth weft yarn of the inner layer is as follows: sinking-floating-sinking; the sinking and floating rule of the binding fourth weft yarn is as follows: sinking-floating-sinking-floating.

On the basis of the above scheme and as a preferable scheme of the scheme: the flame-retardant polyester filament is hollow.

On the basis of the above scheme and as a preferable scheme of the scheme: and a silica gel layer is compounded on the surface of one side of the inner layer.

The utility model has the beneficial effects that: according to the high-temperature-resistant and radiation-resistant polyester fabric, the surface layer is formed by interweaving the radiation-resistant polyester core-spun yarns, so that the polyester fabric has good radiation resistance. And a silica gel layer is coated on one side of the surface layer to improve the high-temperature resistance of the whole fabric. The flame retardant performance of the whole fabric is further improved by adopting the flame retardant polyester filament yarns as the inner layer. The binding weft binding structure ensures that a certain gap is formed between the inner layer and the surface layer to form an air layer, thereby improving the heat insulation capability.

Drawings

FIG. 1 is a schematic structural diagram of a high temperature resistant and radiation resistant polyester fabric according to a first embodiment;

FIG. 2 is a weave structure diagram of a fabric body according to an embodiment;

fig. 3 is a schematic structural diagram of the high temperature resistant and radiation resistant polyester fabric according to the second embodiment.

The designations in the figures illustrate the following: 1-a surface layer; 2-inner layer; 3-a silica gel layer; 101-surface layer first warp yarn; 102-surface layer second warp yarns; 103-surface layer third warp; 104-the fourth warp of the surface layer; 111-the inner first warp yarn; 112-inner layer second warp; 113-inner third warp yarns; 114-the inner fourth warp yarn; 201-surface layer first weft; 202-surface layer second weft; 203-third weft of the surface layer; 204-skin layer fourth weft; 211-inner layer first weft yarn; 212-the inner second weft yarn; 213-inner layer third weft; 214-inner layer fourth weft yarn; 221-binding the fifth weft yarn; 222-binding the second weft yarns; 223-binding the third weft yarns; 224-binding the fourth weft yarn.

Detailed Description

The utility model is further described with reference to the following figures and specific examples.

Example one

This embodiment will be described in detail with reference to fig. 1 and 2. The high-temperature-resistant and radiation-resistant polyester fabric comprises a fabric body formed by interweaving warp yarns and weft yarns, wherein the fabric body is formed by interweaving a tying weft tying weave, the warp yarns comprise surface layer warp yarns and inner layer warp yarns, and the weft yarns comprise surface layer weft yarns, inner layer weft yarns and tying weft yarns; the surface layer warp yarns and the surface layer weft yarns are interwoven to form a surface layer 1, the lining warp yarns and the lining weft yarns are interwoven to form a lining layer 2, and the surface layer and the lining layer are fixedly connected through binding weft yarns. A certain gap is formed between the surface layer 1 and the inner layer 2 formed by the binding weft binding structure to form an air layer, which can play a role in heat insulation and delay heat conduction.

The surface warp yarns and the surface weft yarns are radiation-proof polyester core-spun yarns, each radiation-proof polyester core-spun yarn comprises a core yarn and a coating layer, the core yarn is radiation-proof polyester yarns, and the coating layer is flame-retardant polyester staple fibers; the inner layer warp yarns and the inner layer weft yarns are made of flame-retardant polyester filaments. The surface of the surface layer is coated with a silica gel layer 3. The silica gel layer 3 has good high temperature resistance and good insulating property.

Further, the radiation-proof polyester yarns comprise first elastic polyester yarns, far infrared fiber yarns, second elastic polyester yarns, nano-silver fiber yarns, third elastic polyester yarns and metal yarns, the far infrared fiber yarns are spirally wound on one side of the first elastic polyester yarns, the second elastic polyester yarns are spirally wound on one side of the far infrared fiber yarns, the nano-silver fiber yarns are spirally wound on one side of the second elastic polyester yarns, the third elastic polyester yarns are spirally wound on one side of the nano-silver fiber yarns, and the metal yarns are spirally wound on one side of the third elastic polyester yarns; and the outer surfaces of the first elastic polyester yarns, the far infrared fiber yarns, the second elastic polyester yarns, the nano silver fiber yarns, the third elastic polyester yarns and the metal wires are coated with radiation protection layers.

Further, the surface layer warp yarns comprise a surface layer first warp yarn 101, a surface layer second warp yarn 102, a surface layer third warp yarn 103 and a surface layer fourth warp yarn 104, and the surface layer weft yarns comprise a surface layer first weft yarn 201, a surface layer second weft yarn 202, a surface layer third weft yarn 203 and a surface layer fourth weft yarn 204; the inner layer warp yarns include an inner layer first warp yarn 111, an inner layer second warp yarn 112, an inner layer third warp yarn 113, and an inner layer fourth warp yarn 114, the inner layer weft yarns include an inner layer first weft yarn 211, an inner layer second weft yarn 212, an inner layer third weft yarn 213, and an inner layer fourth weft yarn 214, and the binder weft yarns include a binder first weft yarn 221, a binder second weft yarn 222, a binder third weft yarn 223, and a binder fourth weft yarn 224.

The arrangement rule of the warp yarns is as follows: a surface layer first warp 101, an inner layer first warp 111, a surface layer second warp 102, an inner layer second warp 112, a surface layer third warp 103, an inner layer third warp 113, a surface layer fourth warp 104, and an inner layer fourth warp 114; the arrangement rule of the weft yarns is as follows: the weft yarn comprises surface layer first weft yarns 201, inner layer first weft yarns 211, binding first weft yarns 221, surface layer second weft yarns 202, inner layer second weft yarns 212, binding second weft yarns 222, surface layer third weft yarns 203, inner layer third weft yarns 213, binding third weft yarns 223, surface layer fourth weft yarns 204, inner layer fourth weft yarns 214 and binding fourth weft yarns 224.

Further, based on the warp yarns, the sinking and floating law of the first surface layer weft yarns 201 is as follows: sinking-floating-sinking-floating; the sinking and floating rule of the first weft yarn 211 of the inner layer is as follows: sinking-floating-sinking; the sinking and floating law of the binding first weft yarn 221 is: sinking, floating, sinking and sinking; the sinking and floating rule of the surface layer second weft yarns 202 is as follows: sinking-floating; the sinking and floating rule of the inner layer second weft yarn 212 is as follows: sinking, floating, sinking and sinking; the sinking and floating law of the binding second weft yarn 222: sinking, floating; the sinking and floating rule of the third weft yarns 203 on the surface layer is as follows: floating-sinking-floating; the sinking and floating rule of the third weft yarn 213 in the inner layer is as follows: sinking-floating; the sinking and floating law of the binding third weft yarn 223 is: floating-sinking-floating; the sinking and floating rule of the fourth weft yarn 204 on the surface layer is as follows: floating-sinking-floating; the sinking and floating rule of the fourth weft yarn 214 in the inner layer is as follows: sinking-floating-sinking; the sinking and floating law of the binding fourth weft yarn 224 is: sinking-floating-sinking-floating. Float means that the weft yarn is above the warp yarn and sink means that the weft yarn is below the warp yarn.

Example two

This embodiment will be described in detail with reference to fig. 3. One difference between the high temperature resistant and radiation resistant polyester fabric related to the embodiment and the first embodiment is that: in this embodiment, the flame-retardant polyester filament fiber is hollow. The hollow fibers also have good thermal insulation properties.

The other difference from the embodiment is that a silica gel layer 3 is compounded on one side surface of the inner layer. Further improve the high temperature resistance of the fabric.

The foregoing detailed description of the preferred embodiments of the utility model has been presented. It should be understood that numerous modifications and variations could be devised by those skilled in the art in light of the present teachings without departing from the inventive concepts. Therefore, the technical solutions available to those skilled in the art through logic analysis, reasoning and limited experiments based on the prior art according to the concept of the present invention should be within the scope of protection defined by the claims.

Claims (6)

1. The high-temperature-resistant and radiation-resistant polyester fabric is characterized by comprising a fabric body interwoven by warp yarns and weft yarns, wherein the fabric body is interwoven by adopting a binding weft binding structure, the warp yarns comprise surface layer warp yarns and inner layer warp yarns, and the weft yarns comprise surface layer weft yarns, inner layer weft yarns and binding weft yarns; the surface layer warp yarns and the surface layer weft yarns are interwoven to form a surface layer, the inner layer warp yarns and the inner layer weft yarns are interwoven to form an inner layer, and the surface layer and the inner layer are fixedly connected by binding weft yarns;

the surface warp yarns and the surface weft yarns are radiation-proof polyester core-spun yarns, each radiation-proof polyester core-spun yarn comprises a core yarn and a coating layer, the core yarn is radiation-proof polyester yarns, and the coating layer is flame-retardant polyester staple fibers; the inner layer warp yarns and the inner layer weft yarns are flame-retardant polyester filaments;

the surface of the surface layer is coated with a silica gel layer.

2. The high-temperature-resistant and radiation-resistant polyester fabric according to claim 1, wherein the radiation-resistant polyester yarns comprise first elastic polyester yarns, far-infrared fiber yarns, second elastic polyester yarns, nano-silver fiber yarns, third elastic polyester yarns and metal yarns, the far-infrared fiber yarns are spirally wound on one side of the first elastic polyester yarns, the second elastic polyester yarns are spirally wound on one side of the far-infrared fiber yarns, the nano-silver fiber yarns are spirally wound on one side of the second elastic polyester yarns, the third elastic polyester yarns are spirally wound on one side of the nano-silver fiber yarns, and the metal yarns are spirally wound on one side of the third elastic polyester yarns; and the outer surfaces of the first elastic polyester yarns, the far infrared fiber yarns, the second elastic polyester yarns, the nano silver fiber yarns, the third elastic polyester yarns and the metal wires are coated with radiation-proof layers.

3. The high-temperature-resistant and radiation-resistant polyester fabric according to claim 1, wherein the surface layer warp yarns comprise surface layer first warp yarns, surface layer second warp yarns, surface layer third warp yarns and surface layer fourth warp yarns, and the surface layer weft yarns comprise surface layer first weft yarns, surface layer second weft yarns, surface layer third weft yarns and surface layer fourth weft yarns; the inner layer warp yarns comprise inner layer first warp yarns, inner layer second warp yarns, inner layer third warp yarns and inner layer fourth warp yarns, the inner layer weft yarns comprise inner layer first weft yarns, inner layer second weft yarns, inner layer third weft yarns and inner layer fourth weft yarns, and the binding weft yarns comprise binding first weft yarns, binding second weft yarns, binding third weft yarns and binding fourth weft yarns;

the arrangement rule of the warp yarns is as follows: the surface layer first warp yarns, the inner layer first warp yarns, the surface layer second warp yarns, the inner layer second warp yarns, the surface layer third warp yarns, the inner layer third warp yarns, the surface layer fourth warp yarns and the inner layer fourth warp yarns; the arrangement rule of the weft yarns is as follows: the weft yarn comprises a surface layer first weft yarn, an inner layer first weft yarn, a binding first weft yarn, a surface layer second weft yarn, an inner layer second weft yarn, a binding second weft yarn, a surface layer third weft yarn, an inner layer third weft yarn, a binding third weft yarn, a surface layer fourth weft yarn, an inner layer fourth weft yarn and a binding fourth weft yarn.

4. The high-temperature-resistant and radiation-resistant polyester fabric according to claim 3, wherein based on the warp yarns, the sinking and floating law of the first weft yarns on the surface layer is as follows: sinking-floating-sinking-floating; the sinking and floating rule of the first weft yarn of the inner layer is as follows: sinking-floating-sinking; the sinking and floating law of the binding first weft yarns is as follows: sinking, floating, sinking and sinking; the sinking and floating rule of the second weft yarns on the surface layer is as follows: sinking-floating; the sinking and floating rule of the second weft yarns of the inner layer is as follows: sinking-floating-sinking; the sinking and floating law of the binding second weft yarns: sinking, floating; the sinking and floating rule of the third weft yarns on the surface layer is as follows: floating-sinking-floating; the sinking and floating rule of the third weft yarns of the inner layer is as follows: sinking-floating; the sinking and floating rule of the binding third weft yarns is as follows: floating-sinking-floating; the sinking and floating rule of the fourth weft yarn on the surface layer is as follows: floating-sinking-floating; the sinking and floating rule of the fourth weft yarn of the inner layer is as follows: sinking-floating-sinking; the sinking and floating rule of the binding fourth weft yarn is as follows: sinking-floating-sinking-floating.

5. The high-temperature-resistant and radiation-resistant polyester fabric as claimed in claim 1, wherein the flame-retardant polyester filament is hollow.

6. The high-temperature-resistant and radiation-resistant polyester fabric as claimed in claim 1, wherein a silica gel layer is compounded on a surface of one side of the inner layer.

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