CN218928883U - Thermal insulation composite gilt fabric - Google Patents

Abstract

The utility model discloses a heat-insulating composite gilt fabric, which comprises a base cloth layer and a gilt layer, wherein the gilt layer is adhered to the base cloth layer by a melt adhesive layer, the base cloth layer is a knitted fabric, a graphene layer and a radiation reflecting layer are arranged between the melt adhesive layer and the gilt layer, and are adhered to the melt adhesive layer and positioned below the gilt layer.

Description

Thermal insulation composite gilt fabric

Technical Field

The utility model relates to the technical field of gilt fabric, in particular to a heat-insulating composite gilt fabric.

Background

The fabric treated by the technological processes of high temperature, high pressure and the like on the gilding press is called as gilding fabric. The gold stamping layer is arranged on the gold stamping fabric generally and used for improving the attractiveness of the fabric, and the gold stamping fabric has the characteristics of bright color, wear resistance, weather resistance and the like and is commonly used in the decoration field.

Chinese patent application No. CN201220589858.2 discloses a cloth with elasticity for use in the decoration field. The gold stamping cloth comprises gold stamping cloth and a pattern thereof, wherein the gold stamping cloth is composed of one layer or two layers of pattern cloth; the pattern may be a concave-convex water pattern. The utility model is very suitable for being used in the fields of indoor and outdoor decoration, stage background and the like.

Another example, chinese patent with the publication number CN209365502U discloses a novel fireproof gilt fabric, which comprises a base layer, the basic unit, the longitudinal equidistance of basic unit inner chamber is interluded and is equipped with the radiation protection strip, the basic unit top surface bonds through the binder has the flame retardant coating, flame retardant coating top surface bonds through the binder has nanometer titanium dioxide layer, nanometer titanium dioxide layer top surface bonds through the melt adhesive layer has the gilt layer.

Therefore, the gilt fabric in the prior art has beautiful color, single performance and poor heat retention, and is applied to the clothing field, and the gilt fabric also has the problem of poor comfort.

Disclosure of Invention

The utility model aims to solve the problems in the prior art, and provides a heat-insulating composite gilt fabric which can be applied to the field of clothing and can enhance heat-insulating function and comfort.

In order to achieve the above purpose, the utility model provides a heat-insulating composite gilt fabric, which comprises a base cloth layer and a gilt layer, wherein the gilt layer is bonded on the base cloth layer by a melt adhesive layer, the base cloth layer is a knitted fabric, a graphene layer and a radiation reflecting layer are arranged between the melt adhesive layer and the gilt layer, and the graphene layer and the radiation reflecting layer are bonded on the melt adhesive layer and are positioned below the gilt layer.

Preferably, the graphene layer and the anti-radiation layer are sequentially bonded on the sol layer.

Preferably, the sol layer is a double-component polyurethane composite adhesive.

Preferably, the graphene layer is bonded on the melt adhesive layer by graphene through single-component polyurethane.

Preferably, the anti-radiation layer is bonded on the graphene layer through silver powder and single-component polyurethane.

Preferably, the thickness of the anti-radiation layer and the graphene layer is 10-20 μm.

Preferably, the base cloth layer has a bonding surface and a fluff surface, the fluff surface is located below the bonding surface, and the gold stamping layer is bonded on the bonding surface of the base cloth layer by a melt adhesive layer.

Preferably, the anti-radiation layer and the graphene layer are alternately bonded on the sol layer in a zoned manner and positioned below the gold stamping layer.

The utility model has the beneficial effects that: compared with the prior art, the composite fabric has the advantages that the graphene layer and the anti-radiation layer are arranged between the sol layer and the gold stamping layer, so that the composite fabric can keep the characteristics of the original knitted fabric of the base fabric layer, the knitted fabric is more comfortable and skin friendly to wear in a close-fitting manner, and meanwhile, the heat generated by a human body is locked by the heat absorption effect of the graphene layer and the arrangement of the anti-radiation layer, so that the heat loss is reduced, and the aim of improving the warmth retention of the fabric is achieved.

The features and advantages of the present utility model will be described in detail by way of example with reference to the accompanying drawings.

Drawings

A schematic structural diagram of the first embodiment of fig. 1;

FIG. 2 is a schematic diagram of a second embodiment;

in the figure: 1. a base cloth layer; 2. gilding layer; 3. a sol layer; 4. a graphene layer; 5. a radiation reflecting layer; 6. a bonding surface; 7. a fluff surface.

Detailed Description

Example 1

Referring to fig. 1, the utility model comprises a base cloth layer 1 and a gold stamping layer 2, wherein the base cloth layer 1 is a knitted fabric, the gold stamping layer 2 is bonded on the base cloth layer 1 by a melt adhesive layer 3, a graphene layer 4 and a radiation reflecting layer 5 are arranged between the sol layer 3 and the gold stamping layer 2, and the graphene layer 4 and the radiation reflecting layer 5 are bonded on the sol layer 3 and are positioned below the gold stamping layer 2.

Specifically, the graphene layer 4 and the anti-radiation layer 5 are sequentially bonded on the sol layer 3 from bottom to top. The sol layer 3 is a double-component polyurethane composite adhesive, the graphene layer 4 is formed by bonding graphene on the sol layer 3 through single-component polyurethane, and the anti-radiation layer 5 is formed by bonding silver powder on the graphene layer 4 through single-component polyurethane. A reflecting layer is formed in the single-component polyurethane by silver powder, so that radiant energy is stored or reflected back to the body, and the best warm-keeping effect is generated. When hot air generated by a human body stays in the fabric, bacteria are easy to breed, and the silver powder can adsorb microorganisms and destroy respiratory enzymes on which the microorganisms depend to survive, so that the microorganisms die, and the silver powder has antibacterial and bactericidal effects.

When human body heat passes through graphene, the heat is radiated and radiated in a far infrared form, and is reflected back to the body by matching with the anti-radiation layer 5, so that the warm-keeping effect is improved.

In order to reduce the thickness of the fabric and enhance the comfort, the thickness of the anti-radiation layer 5 and the graphene layer 4 is 10-20 mu m.

Specifically, the base fabric layer 1 has a bonding surface 6 and a nap surface 7, the nap surface 7 is located below the bonding surface 6, that is, is the back surface of the fabric, and the gold stamping layer 2 is bonded on the bonding surface 6 of the base fabric layer 1 by the melt adhesive layer 3. The nap surface 7 on the back ensures the warmth retention of the gilt composite fabric and meets the requirements of fashion fabrics.

Example two

Referring to fig. 2, the difference between the present embodiment and embodiment 1 is only that the arrangement and structure of the graphene layer 4 and the anti-radiation layer 5 are different, in this embodiment, the anti-radiation layer 5 and the graphene layer 4 are in a stripe-shaped split region, and are alternately bonded on the sol layer 3 and located below the gold stamping layer 2, so that in order to improve the heat generating efficiency of the graphene layer 4, an electrode may be connected to the gold stamping layer. The graphene layer 4 is used for generating heat and far infrared light waves to achieve the heating effect, and far infrared rays have the health care function on human bodies, so that the blood circulation can be quickened, and the fatigue feeling can be relieved.

The above embodiments are illustrative of the present utility model, and not limiting, and any simple modifications of the present utility model fall within the scope of the present utility model.

Claims (8)

1. The utility model provides a heat preservation composite gilt surface fabric, includes base cloth layer (1) and gilt layer (2), its characterized in that, base cloth layer (1) is knitting surface fabric, gilt layer (2) are in by melt adhesive layer (3) bond on base cloth layer (1), be equipped with graphite alkene layer (4) and anti-radiation layer (5) between melt adhesive layer (3) and gilt layer (2), graphite alkene layer (4) and anti-radiation layer (5) bond on melt adhesive layer (3) and be located the below of gilt layer (2).

2. The thermal insulation composite gilt fabric according to claim 1, wherein: the graphene layer (4) and the anti-radiation layer (5) are sequentially bonded on the melt adhesive layer (3).

3. The thermal insulation composite gilt fabric according to claim 1 or 2, wherein: the melt adhesive layer (3) is a double-component polyurethane composite adhesive.

4. The thermal insulation composite gilt fabric according to claim 2, wherein: the graphene layer (4) is formed by bonding graphene on the melt adhesive layer (3) through single-component polyurethane.

5. The thermal insulation composite gilt fabric according to claim 4, wherein: the anti-radiation layer (5) is bonded on the graphene layer (4) through silver powder and single-component polyurethane.

6. A thermal insulation composite gilt fabric according to claim 3 wherein: the thickness of the anti-radiation layer (5) and the graphene layer (4) is 10-20 mu m.

7. The thermal insulation composite gilt fabric according to claim 1, wherein: the base cloth layer (1) is provided with a bonding surface (6) and a fluff surface (7), the fluff surface (7) is positioned below the bonding surface (6), and the gold stamping layer (2) is bonded on the bonding surface (6) of the base cloth layer (1) through the melt adhesive layer (3).

8. The thermal insulation composite gilt fabric according to claim 1, wherein: the anti-radiation layer (5) and the graphene layer (4) are alternately bonded on the melt adhesive layer (3) in a zoned manner and positioned below the gold stamping layer (2).

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