CN220040796U - Flower-type reflective cloth - Google Patents

Abstract

The utility model discloses flower-type reflective cloth, which sequentially comprises a micro-bead layer, a first bonding layer, a metal bright layer, a second bonding layer and a cloth layer from top to bottom. According to the utility model, the first bonding layer is coated with the metal light layer by layer, so that the glass beads are inlaid in the first bonding layer, an excellent light reflection effect is generated, and the attractiveness of the cloth is improved. And the first adhesive layer is continuously or discontinuously distributed on the cloth layer, so that glue does not need to be integrally coated on the cloth layer, and the phenomenon that the glue blocks gaps of cloth to influence the air permeability and the comfort of the cloth is avoided. Meanwhile, the first adhesive layer is continuously or discontinuously distributed on the cloth layer, so that pattern combination is realized, an attractive effect is achieved, expensive pattern printing of the reflecting layer is not needed, and therefore, the cost is reduced, and the method is suitable for large-scale popularization and production.

Description

Flower-type reflective cloth

Technical Field

The utility model relates to a flower-type reflective fabric, relates to G02B, and particularly relates to the field of optical element equipment.

Background

With the development of technology and improvement of living standard, the pursuit scope of people for aesthetics is more and more extensive, and the reflective material has different effects under different light environments, so that a plurality of different aesthetic experiences are brought. The reflective material is increasingly applied to clothing cloth, thereby meeting aesthetic requirements of people. But the cloth with reflective performance has harder hand feeling, the reflective fabric has poor air permeability, and the wearing comfort is obviously reduced. And the clothing with the reflective material has poor water washing resistance, and the reflective material can fall off after washing for many times. In addition, the pattern printing of the reflective material requires a higher processing technology, has higher cost and complex steps, and is not suitable for large-scale industrialized production.

The utility model patent CN201010295486.8 discloses an exposure type glass bead reflecting film capable of reflecting colored light and a manufacturing method thereof, wherein a reflecting layer and a transparent color layer are sequentially arranged on a reflecting film substrate, a plurality of glass bead convex mirrors are planted on the transparent color layer through a transparent bonding layer, and each glass bead convex mirror penetrates through the transparent bonding layer and is in point contact with the upper plane of the transparent color layer. The Chinese patent No. 201620371114.1 discloses a glass bead reflecting product for reflecting colored light, wherein a glass bead convex lens penetrates through a transparent bonding layer and is embedded into a part of the reflecting layer, the transparent color layer is directly covered on the glass bead convex lens, the lower surface of the transparent color layer is in hemispherical contact with the glass bead convex lens, more abundant patterns can be customized, the effect of reflecting the multicolor light is achieved, and the angle of reflecting the multicolor light is larger. However, the transparent adhesive layer is entirely coated on the surface of the cloth, so that the hardness hand feeling of the cloth can be affected, and the ventilation comfort of the garment fabric is reduced.

Disclosure of Invention

In order to improve the pattern attractiveness of the reflective cloth, reduce the printing cost and simultaneously give consideration to the characteristics of comfort, ventilation and good hand feeling, the first aspect of the utility model provides the flower-type reflective cloth, wherein the flower-type reflective cloth sequentially comprises a micro-bead layer, a first bonding layer, a metal brightening layer, a second bonding layer and a cloth layer from top to bottom.

As a preferred embodiment, the micro-bead layer is glass micro-beads, the glass micro-beads are wrapped by the first bonding layer, and the exposed height of the glass micro-beads in the first bonding layer is 0-40 mu m.

As a preferred embodiment, the glass beads have the same or different exposed heights in the first adhesive layer, and at least 1/3 of the glass beads have an exposed height of 20-30 μm in the first adhesive layer.

As a preferred embodiment, the glass beads have a diameter of 20 to 80. Mu.m, and more preferably, the glass beads have a diameter of 20 to 50. Mu.m.

As a preferred embodiment, the thickness of the first adhesive layer is 0 to 5 μm, and more preferably, the thickness of the first adhesive layer is 0.1 to 2 μm.

As a preferred embodiment, the metallic lustre layer is wrapped around the first adhesive layer, and the thickness of the metallic lustre layer is 0.1-100nm.

As a preferred embodiment, the second adhesive layer wraps the metal bright layer, and the thickness of the second adhesive layer is 50-500 μm.

As a preferred embodiment, the second adhesive layer is adhered to the cloth layer, and the second adhesive layer is continuously or discontinuously distributed on the cloth layer.

According to the utility model, the second bonding layer is wrapped with the metal light layer, and the first bonding layer is wrapped with the glass beads, so that the bonding fastness of the glass beads can be improved, the water washing resistance is improved, and the glass beads are prevented from falling off; the applicant further discovers that discontinuous distribution of the second adhesive layer on the cloth layer can improve the problems of softness reduction and poor air permeability caused by integral coating of the adhesive in the cloth in the prior art, and the discontinuous distribution of the second adhesive layer can realize the conversion of different patterns according to design originality, so that the soft hand feeling and the air permeability effect of the cloth can not be reduced while the attractiveness of the reflective cloth is improved.

As a preferred embodiment, the thickness of the cloth layer is 1-5 μm, and more preferably, the thickness of the cloth layer is 1-3 μm.

As a preferred embodiment, the metallic bright layer has a wrapping depth of 0-20 μm in the second adhesive layer.

Compared with the prior art, the utility model has the following beneficial effects:

(1) According to the fancy reflecting cloth, the metal light layer is used for wrapping the first bonding layer and the micro-bead layer by layer, so that the glass micro-beads are inlaid in the first bonding layer, an excellent reflecting effect is generated, and the attractiveness of the cloth is improved.

(2) According to the fancy reflecting cloth, the first adhesive layer is continuously or discontinuously distributed on the cloth layer, so that glue does not need to be integrally coated on the cloth layer, gaps of the cloth are prevented from being blocked by the glue, and the air permeability and the comfortableness of the cloth are prevented from being affected.

(3) According to the fancy reflecting cloth, the patterns are combined by continuously or discontinuously distributing the first adhesive layers on the cloth layers, so that an attractive effect is achieved, expensive pattern printing of the reflecting layers is not needed, and therefore, the cost is reduced, and the fancy reflecting cloth is suitable for large-scale popularization and production.

Drawings

Fig. 1 is a schematic side view of a flower-type reflecting fabric according to embodiment 1 of the present utility model;

fig. 2 is a schematic side view of the fancy reflection fabric in embodiment 2 of the present utility model.

In the figure: 1. a cloth layer; 2. a second adhesive layer; 3. a metal bright layer; 4. a first adhesive layer; 5. a layer of microbeads.

Detailed Description

Example 1

A flower-type reflective cloth, as shown in fig. 1: the structure of the flower-type reflective fabric sequentially comprises a micro-bead layer 5, a first bonding layer 4, a metal bright layer 3, a second bonding layer 2 and a fabric layer 1 from top to bottom.

The micro-bead layer is glass micro-beads, the glass micro-beads are wrapped by the first bonding layer, and the exposed height of the glass micro-beads in the first bonding layer is 20 mu m.

The glass beads are exposed in the first bonding layer to the same height.

The diameter of the glass beads is 40 mu m, and the thickness of the first bonding layer is 1 mu m.

The second bonding layer wraps the metal bright layer, and the thickness of the second bonding layer is 300 mu m.

The second bonding layer is bonded with the cloth layer, and the second bonding layer is discontinuously distributed on the cloth layer.

The thickness of the cloth layer was 2.5 μm.

The wrapping depth of the metal bright layer on the second bonding layer is 20 mu m.

Example 2

A flower-type reflective cloth, as shown in fig. 1: the structure of the flower-type reflective fabric sequentially comprises a micro-bead layer 5, a first bonding layer 4, a metal bright layer 3, a second bonding layer 2 and a fabric layer 1 from top to bottom.

The micro-bead layer is glass micro-beads, the glass micro-beads are wrapped by the first bonding layer, and the exposed height of the glass micro-beads in the first bonding layer is 0-40 mu m.

The glass beads have different exposure heights in the first bonding layer, and the exposure height of 1/3 of the glass beads in the first bonding layer is 20 mu m; the height of 1/6 quantity of glass beads exposed in the adhesive B is 35 mu m, the height of 1/6 quantity of glass beads exposed in the adhesive B is 25 mu m, the height of 1/6 quantity of glass beads exposed in the adhesive B is 15 mu m, and the height of 1/6 quantity of glass beads exposed in the adhesive B is 0 mu m.

The diameter of the glass beads is 40 mu m, and the thickness of the first bonding layer is 1 mu m.

The second bonding layer wraps the metal bright layer, and the thickness of the second bonding layer is 300 mu m.

The second bonding layer is bonded with the cloth layer, and the second bonding layer is discontinuously distributed on the cloth layer.

The thickness of the cloth layer was 2.5 μm.

The wrapping depth of the metal bright layer on the second bonding layer is 20 mu m.

Claims (7)

1. The flower-type reflective cloth is characterized in that the flower-type reflective cloth sequentially comprises a micro-bead layer, a first bonding layer, a metal bright layer, a second bonding layer and a cloth layer from top to bottom;

the micro-bead layer is made of glass micro-beads, the glass micro-beads are wrapped by the first bonding layer, and the exposed height of the glass micro-beads in the first bonding layer is 0-40 mu m;

the metal light layer wraps the first bonding layer, the second bonding layer wraps the metal light layer, and the wrapping depth of the metal light layer in the second bonding layer is 0-20 mu m;

the second adhesive layer is adhered to the cloth layer, and the second adhesive layer is continuously or discontinuously distributed on the cloth layer.

2. The structured reflective cloth according to claim 1, wherein the glass beads have the same or different exposed heights in the first adhesive layer, and at least 1/3 of the glass beads have an exposed height of 20 to 30 μm in the first adhesive layer.

3. The fancy reflection cloth of claim 2 wherein the glass microsphere has a diameter of 20-80 μm.

4. The structured reflective cloth according to claim 1, wherein the thickness of the first adhesive layer is 0 to 5 μm.

5. The fancy reflection cloth of claim 1 wherein the metallic bright layer has a thickness of 0.1-100nm.

6. The structured reflective cloth according to claim 1, wherein the thickness of the second adhesive layer is 50 to 500 μm.

7. The fancy reflection cloth of claim 1 wherein the thickness of the cloth layer is 1-5 μm.