KR100529593B1 - Hot stamping foil - Google Patents

Abstract

The present invention provides a high-quality texture such as natural corrosion by partially evaporating the metal layer by a chemical method during the manufacture of a deposited thermal transfer foil containing an aluminum metal layer made of aluminum deposition or a metallic powder by applying a metal powder to produce a metallic luster. The three-dimensional design of the present invention relates to a thermal transfer foil characterized by the fact that wastewater is not generated during production.

The characteristic configuration of this thermal transfer foil is as follows.

Base film 30; A release agent layer 31 coated on the base film to facilitate removal of the base film after transfer; The metal powder is applied on the release agent layer to obtain metallic luminescence, and acid treatment is performed on the metal powder coated portion with the coating layer 35 coated thereon, whereby the remaining portion except for the coating layer is coated by chemical reaction with acid. A metal layer 34 etched to have a three-dimensional pattern; A coloring layer 36 painted on the coating material layer; And an adhesive layer 37 coated on the colored layer.

Description

Hot stamping foil having a three-dimensional pattern by a chemical method

The present invention provides a high-quality texture such as natural corrosion by partially evaporating the metal layer by a chemical method during the manufacture of a deposited thermal transfer foil containing an aluminum metal layer made of aluminum deposition or a metallic powder by applying a metal powder to produce a metallic luster. The three-dimensional design of the present invention relates to a thermal transfer foil having a three-dimensional pattern by a chemical method characterized by the fact that no waste water is generated during production.

There are four types of thermal transfer foils that give a three-dimensional pattern to a subject after thermal transfer.

1) Attachment type (Ticking thermal transfer foil)

As shown in FIG. 1, a so-called two-liquid reactive coating agent reacting with a polyol and an isocyanate on the base film 1 is applied as a gravure cylinder engraved with dots or thin lines to prevent separation from the base film. ).

On the coating layer, a release agent is applied to form a release agent layer 3, and a printing layer 4 is formed thereon.

The gold layer (or transparent layer) 5 and the deposition layer 6 may be made or omitted on the printed layer, and finally, the adhesive layer 7 is formed.

When the attachment type thermal transfer foil is thermally transferred onto a subject and the base film 1 is separated, a three-dimensional point or a thin line is formed on the transferred surface of the subject while the base film and the coating layer are simultaneously separated.

(problem)

The remaining amount after the use of the two-component reaction coating agent treatment problem and the resulting cost increase factor.

In addition, the three-dimensional effect is inferior by providing a three-dimensional effect only to the mold release agent layer 3.

In addition, only a very limited three-dimensional effect such as thin lines or dots is produced, thereby limiting the variety of designs.

2) Flush type (partial deposition)

As shown in FIG. 2, a release agent is coated on the base film 8 to form a release agent layer 9, and a gravure printing is performed thereon to form a print layer 10.

The gold clear layer 11 is apply | coated on the said printing layer, and the water-soluble coating layer 12 washable on it is apply | coated to the site from which aluminum metal is to be removed.

An aluminum deposition layer 13 is formed on the water-soluble coating layer through an aluminum deposition process. At this time, the fabric made of the aluminum deposition layer washes the portion where the water-soluble coating layer 12 is formed while passing through a washing machine washed several times as separate water.

The adhesive layer 14 is formed in the raw unit after cleaning.

(problem)

The intaglio of the aluminum deposition layer 13 formed by washing the water-soluble coating layer 12 by the washing process is clear and distinct, so that a natural texture, that is, a high-quality texture design can not be obtained, but only partially removed aluminum. none.

In addition, this process is rarely used because of the environmental pollution problem due to the increase of the air due to the washing process and a large amount of waste water generated during washing.

3) Flush type of alkaline aqueous solution

A release agent layer 16 is formed on the base film 15 by forming a release agent layer 16, and a printing layer 17 is formed by printing as a gravure cylinder on the release agent layer, and a gold creeper layer 18 is applied on the printing layer.

An aluminum deposition layer 19 is formed on the gold creeper layer 18 using a vacuum evaporator, and an alkaline coating layer is coated on the aluminum deposition layer by applying an alkali resistant coating agent using a gravure cylinder on a portion where aluminum is to be left. ).

Next, while washing through the washing machine several times in order to rinse with an aqueous alkali solution, the exposed part of the aluminum deposition layer 19 in which the alkaline coating layer 20 is not formed is washed away. In this case, a large amount of wastewater generated while washing the aluminum deposition layer is inevitably generated.

Finally, the adhesive layer 21 is formed on the cleaned aluminum deposition layer.

(problem)

Since the aluminum intaglio formed by cleaning the aluminum part of the aluminum metal by the aqueous solution is clearly and clearly distinguished, it is impossible to obtain a high-quality texture design, but only partially removes aluminum.

In addition, the number of times is increased by washing with alkaline aqueous solution several times in a separate washing machine, this method is also rarely adopted because of the large amount of waste water generated during the washing.

4) Flushing type to wash after thermal transfer

The release agent layer 23 is formed by applying a release agent on the base film 22, and the water-soluble cree 24 is applied to the portion to be washed out with water using a gravure cylinder on the release agent layer.

After applying the water-soluble creas, the protective cree 25 is applied to the entire surface in order to protect the printing surface during the post-cleaning operation, and the printed layer 26 on which the desired design is printed is formed on the protective cree.

Next, the gold cree layer 27 and the deposition layer 28 are sequentially stacked on the printed layer. In this case, when the metallic luster is not desired, the gold cree layer 27 and the deposition layer 28 may be omitted.

Finally, an adhesive layer 29 is formed on the deposition layer 28.

After the thermal transfer film made as described above is thermally transferred to the subject, the base film 22 is separated and removed, and the transferred subject is washed with water several times in a separate cleaner to create a subject having a three-dimensional design. At this time, a large amount of waste water is inevitably generated.

(problem)

This method uses thermal transfer foil to thermally transfer the subject and then washes the water-soluble creeper with the subject as water.

By providing a three-dimensional effect to the release agent layer 23, it is impossible to give a three-dimensional pattern to the deposition layer 28 due to the limitation that only a simple intaglio effect can be produced, and the waste water treatment caused by the washing process is pointed out as a problem.

Accordingly, the present invention has been made to solve the above problems, and an object thereof is to provide a thermal transfer foil having a three-dimensional pattern by a chemical method capable of freely implementing three-dimensional design.

In addition, by etching the metal layer by a chemical reaction it is possible to produce a natural and luxurious texture design, and to provide a thermal transfer foil having a three-dimensional pattern by a chemical method that does not generate waste water at all.

In addition, since there is no need for a separate device such as a washing machine for implementing the three-dimensional formation layer, it is possible to reduce the investment of air and manufacturing equipment, and to provide a thermal transfer foil having a three-dimensional pattern by a chemical method capable of in-line manufacturing.

The purpose of this invention is

Base film; A release agent layer coated on the base film to facilitate removal of the base film after transfer; The metal powder is applied on the release agent layer to obtain metallic luminescence, and the acid portion is treated in a state where the coating layer is coated on the portion to which the metal powder is coated, so that the remaining portions except the coated layer are etched by chemical reaction with acid to be steric A metal layer having a pattern; A coloring layer colored on the coating material layer; It is achieved by constructing an adhesive layer coated on the colored layer.

In addition, it is achieved by further comprising a printed layer in which a specific pattern is printed on the release agent layer.

In addition, the base film; A release agent layer coated on the base film to facilitate removal of the base film after transfer; After coating a metal such as aluminum on the release agent layer through vacuum deposition, the acid treatment is performed in a state in which the coating layer is coated on the portion where the metal is to be left, so that the remaining portions except the coated layer are subjected to chemical reaction with acid. A metal layer etched by the metal layer having a three-dimensional pattern; A coloring layer colored on the coating material layer; It is achieved by constructing an adhesive layer coated on the colored layer.

In addition, it is achieved by further comprising a printed layer in which a specific pattern is printed on the release agent layer.

In addition, in the thermal transfer foil formed by laminating a plurality of resin layers and a metal layer, the remaining portion except for the portion coated with the acid is treated with acid by acid treatment in a state where the coating layer is coated on the portion to leave the metal on the metal layer. It is achieved by etching it by reaction so that it has a three-dimensional pattern.

Hereinafter, an embodiment of the present invention will be described in more detail with reference to FIG. 5. Substrate films, release agents, printing inks, gold cree or transparent cree, primers, adhesives, and the like described below presuppose that the same materials used in the manufacture of ordinary thermoelectric foils are used.

The thermal transfer foil of the present invention is a release agent composed of ketone, ethacetate, and toluene mainly composed of an acrylic resin on a base film 30 made of a polyester, polypropylene, or polyvinyl chloride-based film having excellent heat or matte thermal stability. Layer 31 is applied.

On the release agent layer 31, a desired pattern (design) is printed by a gravure cylinder (not shown), thereby forming a printing layer 32 forming a primary design. In this case, the printed layer may be omitted if a simple design is desired.

On the printing layer 32 is formed by applying a gold or transparent clear layer 33 made of a mixture of resin and solvent to the front for adhesion and protection of the metal layer to be described later. This cree layer corresponds to a protective layer for protecting the metal layer 32.

On the creeper layer 33, a metal such as aluminum is vacuum-deposited or a metal powder is coated to form a metal layer 34.

On the metal layer, when the metal layer is acid-treated in a state in which a coating layer 35 made of primer is coated on a portion where a metal is to be left using a gravure cylinder, only the exposed portion except for the coating layer is coated. It is etched and corroded by this chemical reaction.

At this time, if the unfinished thermal transfer foil wound in a roll state after the acid treatment is left at room temperature for about 48 hours, the chemical reaction is terminated naturally.

When the chemical reaction is terminated, a three-dimensional pattern such as a naturally eroded portion of the portion etched by the chemical reaction is not clear and a high quality texture can be obtained.

As can be seen from the formation process of the three-dimensional pattern by the chemical method is a simple process of acid treatment and room temperature left it is easy to work, there is no need for a separate device or machine has the advantage that inline manufacturing is possible.

On the metal layer 34 after the acid treatment, a colored layer 36 having a full color in a desired color is formed. In this case, for example, when the entirety of the pearl ink is colored, the pearl color is expressed through the etched portion of the metal layer 34, so that the pearl color is rearward of the printing layer 32 when viewed from the base film 30 side. It can be expressed to produce a three-dimensional effect due to the distance difference between the print layer and the metal layer.

Finally, an adhesive layer 37 is formed on the colored layer 36 to transfer the design on the subject, and a thermal adhesive layer having different components according to the type of the subject is formed.

As described above, the thermal transfer foil of the present invention

By etching and etching the metal layer by chemical reaction, the secondary design layer can be formed with a distance difference while the primary design layer is secured by the printing layer in front, thereby producing a three-dimensional effect, and by chemical reaction The corroded metal layer can obtain a surface such as natural corrosion and can produce high quality texture, thereby enhancing aesthetics.

1 is a conventional thermal transfer foil 1

2 is a conventional thermal transfer foil 2

3 is a conventional thermal transfer foil 3

4 is a conventional thermal transfer foil 4

5 is a block diagram of a thermal transfer foil according to the present invention

[Description of Symbols for Main Parts of Drawing]

30. Base film 31. Release agent layer

32. Printing Layer 33. Cree Layer

34. Metal layer 35. Coating layer

36. Colored layer 37. Adhesive layer

Claims (5)

delete delete Base film 30; A release agent layer 31 coated on the base film to facilitate removal of the base film after transfer; After coating a metal such as aluminum on the release agent layer through vacuum deposition, acid treatment is performed in a state in which the coating layer 35 is coated on a portion to which the metal is to remain, so that the remaining portion except for the coating layer is coated with acid. A metal layer 34 etched by a chemical reaction and having a three-dimensional pattern; A coloring layer 36 painted on the coating material layer; An adhesive layer 37 coated on the colored layer; Deposition thermal transfer foil having a three-dimensional pattern by a chemical method characterized in that consisting of. The method of claim 3, wherein Evaporation thermal transfer foil having a three-dimensional pattern by a chemical method characterized in that it further comprises a printing layer (32) is printed on the release agent layer (31). In the thermal transfer foil formed by laminating a plurality of resin layers and metal layers, A chemical method having a three-dimensional pattern by etching a portion of the coating layer 35 by acid treatment in a state in which a coating layer 35 is coated on a portion to leave a metal on the metal layer 34 by a chemical reaction with an acid. Thermal transfer foil having a three-dimensional pattern by.