KR100506298B1 - method of treatment self colored reflective - Google Patents

Abstract

The present invention provides a method for creating high added value by providing a retroreflective function on a graphic surface of a finished product without producing a sticker or sheet having a separate retroreflective graphic, etc., thereby providing superior value in terms of merchandise and economy. will be.

Description

Method of treatment self colored reflective

The present invention relates to a retroreflective processing method based on all products subjected to graphic processing, and includes a retroreflective method on a product or fabric that is subjected to graphic processing in any form, such as screen printing, sublimation printing, printing, printing, or a live-printed fabric. There is a feature that can greatly increase the value of goods by giving a function.

In other words, the graphic formed on the product or fabric that has been processed in any form, such as screen printing, sublimation printing, printing, printing, or a live-printed fabric as described above, is composed of various patterns and colors, but has its own retroreflective function. I don't have it. Therefore, in order to make the graphic recursive, a printing layer having the same pattern and color as the graphic is formed under the glass bead 40 layer, and a white ink or aluminum deposition film having a reflective function under the upper printing layer. To form a sticker having a retroreflective function or a thermal transfer sticker, and then attach or fix it on the surface of various products.

However, the above-described technique is very difficult to impart a retroreflective function when an ink or pigment having poor light transmittance is used to form a printed layer, while a pattern is vividly expressed and recursive at the same time even when an ink or pigment having excellent light transmittance is used. Making it functional is not easy either. In addition, it is not easy to manufacture a product that satisfies both the clear pattern and the excellent retroreflective function, and a lot of research and development cost must be invested. In fact, the retroreflective technology is applied to the patterns or logos formed on the surface of many products in advance. It is almost impossible to apply and build it and then fix it back into the product, which is why the excellent features and product value of reflex reflection are acknowledged but are not widely used. In addition, there is a problem in that the retroreflective material manufactured as described above is fixed to the product one by one, so that problems such as durability or anti-deformation of the product are not so good and the researches for solving the problem are continued. As mentioned above, by simply giving the retroreflective function to the graphic surface of the finished product on which any type of graphic is printed without the retroreflective function, the original pattern and color are expressed intactly and satisfactorily and at the same time recursive. The purpose is to make a retroreflective finished product that is highly commercial and economical in terms of overall reflection.

Accordingly, the present invention provides a method of creating high added value by providing a retroreflective function to a graphic surface of an already completed product without producing a sticker or sheet having a separate retroreflective graphic, and thus, having excellent merchandise and economy. It is.

To this end, the present invention, the first step of making a base film (10) by coating a thickness of 50 micron or less PE resin on one surface of the PET film; A second step of melting the PE resin by passing the base film 10 into a heating chamber 20 where a temperature of 150 ° C. or less is generated; A third step of dropping and coating the glass beads 40 having a diameter of 100 microns or less through the glass bead dropping device 30 onto the molten PE resin layer on the base film 10 passing through the heating chamber 20; A fourth step of forming a transparent hot melt layer 50 having a thickness of 100 microns or less on the surface of the glass bead 40 coating layer; A fifth step of cutting through a manual or automatic machine the sheet made through the fourth step so that the graphic on the surface is substantially equal to or slightly larger than the outline of the graphic of the processed product 60; According to the graphic contour of the product 60 processed graphics on the surface and the transparent hot melt layer 50 of the sheet cut through the fifth process is contacted by applying a heat of 200 ℃ or less to iron the product (60) A sixth step of allowing the transparent hot melt layer 50 to be strongly adhered to the graphic layer of the sheet) such that the sheet made through the fifth process covers the graphic layer; After the sixth process is finished, the base film 10 is removed, so that the glass bead 40 layer is exposed, and thus the seventh process is provided to provide the retroreflective function to the graphic layer.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The first step of making the base film 10 by coating a PE resin on the surface of one side of the PET film to a thickness of 100 microns or less, coating the PE resin on the surface of the PET film is a roll coating device or a spray coating device, etc. It can be carried out through and since these devices are already used in various fields, a detailed description thereof will be omitted.

Next, a second process of melting the PE resin by passing the base film 10 into a heating chamber 20 where a temperature of 150 ° C. or less is generated is performed. It is suitable in the range between 130 ° C and 150 ° C which can be melted. In addition, the heating chamber may use a radiant heat heating method or an electric heater method, and the manufacturing technology of such a heating chamber is also known, and thus detailed description thereof will be omitted.

Next, a third process of dropping and coating the glass beads 40 having a diameter of 100 microns or less through the glass bead dropping device 30 onto the molten PE resin layer on the base film 10 passing through the heating chamber 20. When performing, the glass bead dropping device 30 has a variety of models that are currently used in the company to produce a retroreflective fabric. When the glass beads 40 fall down on the molten PE resin layer as described above, the glass beads are arranged in a horizontal line with almost minimal spacing between the glass beads as shown in the figure, and when the PE resin is cured, they are firmly fixed. do. Of course, the glass beads accumulated on the glass bead layer arranged and fixed in one horizontal row may be recovered through a vacuum recovery device and used again after being fed back into the glass bead dropping device 30. On the other hand, the diameter of the glass beads 40 used in the present invention is preferably within the above range, but is not necessarily limited to those described in the present invention.

Subsequently, a fourth process of forming a transparent hot melt layer 50 having a thickness of 100 microns or less on the surface of the glass bead 40 coating layer is performed. Naturally, other resins having physical properties can be used. In this case, the coating thickness of the hot melt layer is good within the above-described range, and if it is excessively formed, this results in inadequate results in the clarity of the color of the pattern and the retroreflective function.

Next, a fifth process of cutting the sheet made through the fourth process by manual or automatic machine (computer cutting) so that the surface of the product 60 is roughly the same as or slightly larger than the outline of the graphic of the processed product 60. This work has no difficulty or technical problems.

Subsequently, a cut sheet made through a fifth process is used to achieve the object of the present invention, wherein the transparent hot melt layer 50 of the cut sheet is brought into contact with the graphic surface of the product 60 on which the graphic has been treated. After the ironing is performed by applying a heat of 200 ° C. or lower, a sixth step of strongly adhering the transparent hot melt layer 50 of the sheet cut to the graphic layer of the product 60 is strongly bonded. That is, for example, the present invention is carried out on a color drawing (or a solid drawing, a logo, etc.) printed on a T-shirt as in the sixth step, and the cut sheet k made through the fifth step is cut out of the color drawing. The cutting is done by manual or automatic machines, almost the same size or slightly larger than the overall contour. Subsequently, the hot melt layer of the cut sheet is brought into contact with the color drawing (graphic), and the contour of the cut sheet and the color drawing is aligned, and then ironed, and the hot melt layer is strongly bonded with the color drawing (graphic). Be sure to Accordingly, the cut sheet is fixed on the product as if covering the color pattern.

Finally, when the sixth process is completed and the seventh process of removing the base film 10 to expose the glass bead 40 layer is completed, the present invention is completed, but the graphics formed on the existing product are completely damaged. The present invention can be applied to the surface of any design without making or modifying it, and without applying a separate pretreatment step, so that any form of design is provided with a retroreflective function.

As described above, the present invention provides a retroreflective function by providing a retroreflective function to any graphic by performing the technique of the present invention on the surface of the graphic without any graphic being formed on the surface of any product. Compared to the use of objects, workability, productivity, durability, value-added, economics, and the like are incomparably improved.

1 is a process diagram showing the practice of the present invention.

<Description of the symbols for the main parts of the drawings>

10: base film 20: heating chamber

30: glass bead dropping device 40: glass bead

50: transparent hot melt layer 60: graphic product

Claims (2)

A first step of making a base film 10 by coating PE resin with a thickness of 100 microns or less on one surface of the PET film; A second step of melting the PE resin by passing the base film 10 into a heating chamber 20 where a temperature of 150 ° C. or less is generated; A third step of dropping and coating the glass beads 40 having a diameter of 100 microns or less through the glass bead dropping device 30 onto the molten PE resin layer on the base film 10 passing through the heating chamber 20; A fourth step of forming a transparent hot melt layer 50 having a thickness of 100 microns or less on the surface of the glass bead 40 coating layer; A fifth step of cutting through a manual or automatic machine the sheet made through the fourth step so that the graphic on the surface is substantially equal to or slightly larger than the outline of the graphic of the processed product 60; According to the graphic contour of the product 60 processed graphics on the surface and the transparent hot melt layer 50 of the sheet cut through the fifth process is contacted by applying a heat of 200 ℃ or less to iron the product (60) A sixth step of allowing the transparent hot melt layer 50 to be strongly adhered to the graphic layer of the sheet) such that the sheet made through the fifth process covers the graphic layer; After the sixth process is finished, the seventh process is performed by removing the base film 10 to expose the glass bead 40 layer so that the retroreflective function is applied to the graphic layer. Retroreflective treatment based on all products. The method of retroreflective treatment according to claim 1, wherein the transparent hot melt layer (50) is a urethane-based resin.