KR20190035136A - Method for manufacturing gold foil printing having double image and gold foil printing thereof - Google Patents

Abstract

The present invention relates to a method for manufacturing a gold sheet-printed material having a dual image, which is capable of remarkably improving durability of a gold sheet-printed material, and a gold sheet-printed material thereof. The method of the present invention comprises the steps of: generating an image layer; forming a hole penetrating a base film; forming a pore; attaching a gold sheet to an aluminum plate; attaching the gold sheet to a surface opposite to a surface where the image layer is generated; and forming a coating layer.

Description

METHOD FOR MANUFACTURING GOLD FOIL PRINTING HAVING DOUBLE IMAGE AND GOLD FOIL PRINTING THEREOF BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

More particularly, the present invention relates to a method of manufacturing a gold leaf print having a dual image and a gold leaf print.

Ornaments such as plaques, commemorative plaques or plaques are generally produced by printing images on metal plates. These ornaments are often produced by printing an image on a gold foil for a luxurious taste as a decoration. At this time, techniques for printing an image on the gold foil include an offset printing method and a silk screen printing method.

The offset printing method is not an indirect printing method in which the printing plate and the printing object are in direct contact with each other, but the printing contents are transferred to a rubber blanket and printed on the printing object. That is, the offset printing method is a process of transferring the print contents from the printing plate to the rubber blanket, and from the rubber blanket to the printing object in the middle in the order of the rubber blanket. The offset printing method has the advantage of improving the print quality and preventing damage to the printing plate. However, in the gold foil printing, there is a problem that it is difficult to expect a good printed matter because the gold foil having a large ductility and a large silver foil is pressed by the rubber blanket and spread.

The silk screen printing method is a printing method in which ink is fixed on a printing object, and a hole is formed on a silk cloth in accordance with an image, and ink is printed down through the hole. The silk screen printing method has an advantage in that it can print on various printing objects by using one silk plate, but it has a drawback in that it is difficult to print color photographs properly because there is a limit in generating a small hole size of a silk screen .

In addition, there is a method in which gold foil is adhered to paper such as Korean paper, and is directly printed on the gold foil by using an offset printing method on the gold foil. However, such a printing method has a problem in that the coloring thereof is deteriorated because it needs to be printed on the gold leaf itself. To overcome this problem, a method has been proposed in which an image is printed on the film by an offset method, and a film on which the image is printed is bonded to the gold foil. However, the color and texture of the gold foil were not properly expressed by the film adhered to the gold foil, and the film was peeled off from the gold foil over time.

Korean Registered Utility Model No. 20-0190447, "Gilded Print"

A gold foil printing method and a gold foil printing method having dual images capable of expressing another image in addition to an image printed on a film by expressing the color and texture of the original gold foil while gluing a film printed with an image on the gold foil.

It is also intended to provide a method for manufacturing a gold foil print having a dual image and a gold foil print which can effectively prevent the phenomenon that the film is peeled off from the gold foil and that the aluminum foil and the gold foil are separated from each other effectively and durably .

A method for manufacturing a gold foil print having a dual image according to an embodiment of the present invention is a method for manufacturing a gold foil print using a gold foil adhered to a front portion of a plaque having an aluminum plate as a base plate,

(1) printing an image with UV (Ultra Violet) ink on one side of a base film to produce an image layer;

(2) forming a hole through the base film at predetermined intervals in a predetermined region by using a laser on the base film that has generated the image layer in the step (1);

(3) oxidizing the coating of the aluminum plate to form voids;

(4) bonding the gold foil to the aluminum plate having the void in the step (3);

(5) bonding the gold foil adhering to the aluminum plate in the step (4) to the opposite surface of the base film on which the image layer is formed in the step (2); And

(6) forming a coating layer on the surface of the base film on which the image layer is formed.

Preferably, the step (1)

In the whole halftone, you can print white so that Yellow is 20%, Magenta is 10%, and Cyan is 4%.

More preferably, the hole of step (2)

The diameter may be 0.3 mm to 1 mm.

Even more preferably, the step (2)

The predetermined area may be a graphic or textual shape.

Even more preferably, the step (2)

A hole may be formed in the base film by irradiating a laser beam on a surface opposite to the surface on which the image layer is formed.

Even more preferably, step (3)

The coating of the aluminum plate can be oxidized by using a rectifier containing hydrochloric acid.

Even more preferably, the step (5)

A laser beam is irradiated from the aluminum plate to fuse one surface of the base film contacting the gold foil and to adhere using a high pressure generated due to bubbles generated in the melted base film.

Even more preferably, the step (5)

A pulsed laser beam can be irradiated.

Even more preferably,

The melting point may be lower than the aluminum plate and the gold foil.

Even more preferably, the step (5)

The spot size of the laser beam may be 0.02 mm.

In addition, the gold leaf print according to the embodiment can be manufactured by a method of manufacturing a gold leaf print having a dual image.

A method of manufacturing a gold foil print having a dual image according to the disclosure, and a gold foil printing method, wherein a gold foil is adhered to a film printed with an image, and holes are formed in a part of the film to express the original color and texture of the gold foil, You can express another image besides the image.

The method of manufacturing a gold foil print having a dual image according to the disclosure and a gold foil printing method include a phenomenon in which a film is peeled from a gold foil by bonding an aluminum foil, a gold foil and a film using a laser, The durability of the gold leaf printed matter can be remarkably improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a configuration of a method for manufacturing a gold leaf print having a dual image according to an embodiment; FIG.
2 is a view showing a base film and a gold foil in a method of manufacturing a gold foil print having a dual image according to an embodiment.
3 is a view of an aluminum plate having voids in a method of manufacturing a gold foil print having a dual image according to an embodiment.
4 is a view showing a state in which an aluminum plate, a gold foil, and a base film are adhered in a method of manufacturing a gold foil print having a dual image according to an embodiment.
5 is a view showing a configuration of a gold leaf print according to another embodiment;

In the following description of the disclosed embodiments, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the disclosed embodiments unnecessarily obscure.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a configuration of a method for manufacturing a gold leaf print having a dual image according to an embodiment. FIG. A method of manufacturing a gold foil print having a dual image according to an exemplary embodiment is a method of manufacturing a gold foil print using a gold foil 200 adhered to a front portion of a plaque having an aluminum plate 100 as a base plate, (S100) of printing an image by using UV (Ultra Violet) ink on one side of the base layer 300 to produce an image layer 310. In step S100, the base layer 300, on which the image layer 310 is formed, (S300) of oxidizing the coating of the aluminum plate (100) to form the gap (110); and a step (S300) of oxidizing the coating of the aluminum plate The image layer 310 of the base film 300 on which the hole 320 is formed is formed in step S200 by attaching the gold foil 200 to the aluminum plate 100 on which the void 110 is formed Side and the aluminum plate 100 in step S400 Foil may include the step (S600) of forming the coating layer 400 to the surface to form the image layer 310 in step (S500) and the base film 300 to be bonded to 200. The Hereinafter, each step of the method for manufacturing a gold leaf print having a dual image according to an embodiment will be described in detail.

In step S100, the image layer 310 may be formed by printing an image on the one side of the base film 300 with UV ink. Here, the base film 300 may be a plastic resin that is not deformed by the rubber blanket during printing due to the offset printing method. In particular, the base film 300 is preferably made of PET (polyethylene terephthalate) resin. However, the base film 300 is not limited thereto, and may be made of PVC (Polyvinyl Chloride), Acrylic, Polycarbonate or ABS (Acrylonitrile Butadiene Styrene) Of resin material. The image layer 310 may be a layer on which the image is printed on the base film 300. The image of the image layer 310 may be printed in an offset printing method using UV inks. Since the UV ink adheres to the printing object, it is suitable to print an image on the base film 300, and the color can be maintained for a long time even when exposed to sunlight.

FIG. 2 is a view showing a base film 300 and a gold leaf 200 in a method of manufacturing a gold leaf print having a dual image according to an embodiment. In step S100, white can be printed so that Yellow is 20%, Magenta is 10%, and Cyan is 4% at the entire halftone dot. The base film 300 is adhered to the gold foil 200 as described later so that the image printed on the image layer 310 is transferred onto the gold foil 200 . Therefore, the background color of the image printed on the image layer 310 appears as gold, and in particular, it may look much yellower than the original color. Therefore, in order to compensate for this deflection, the hue must be adjusted by adding yellow, red and blue. In general, printed matter is represented by an image in which fine points are superimposed. This fine point is called a dot. In step S100, in the case of white, the white color can be corrected by printing so that the yellow color is 16 to 24%, the magenta color is 8 to 12%, and the cyan color is 3 to 5% at the entire halftone dot. Preferably, in step S100, in the case of white, white can be corrected by printing so that Yellow is 20%, Magenta is 10%, and Cyan is 4% at all halftone dots. That is, in step S100, even when the image printed on the image layer 310 is disposed on the gold leaf 200 by adjusting the halftone dot ratio of yellow, magenta and cyan in the halftone dot printed on the image layer 310, Can be expressed.

Step S200 may form a hole 320 through the base film 300 at a uniform interval in a predetermined region using a laser on the base film 300 that has generated the image layer 310 in step S100 . At this time, the diameter of the hole 320 may be 0.3 mm to 3 mm, but preferably 0.3 mm to 1 mm. If the diameter of the hole is smaller than 0.3 mm, it is difficult to confirm with the naked eye. If it is larger than 3 mm, it is difficult to provide a beauty to be expressed as a fine hole on the base film 300. Further, if the diameter difference between the largest hole and the smallest hole is limited to about three times, the image can be expressed more finely through the plurality of holes, so that the diameter of the largest hole can be limited to 1 mm. At this time, the hole 320 having a large diameter is formed at the center of the predetermined region, and the hole 320 having a smaller diameter is formed as the position is shifted from the center, so that the outline of the region can be expressed neatly.

The conventional gold foil print was produced by printing an image on the base film 300 and adhering the base film 300 on the gold foil 200. Therefore, even if the base film 300 is thin, the color and texture of the gold foil 200 can not be properly expressed due to the refraction of the light due to the base film 300 and the like. However, since the fine holes 320 are formed in the base film 300, even if the base film 300 is adhered to the base film 300, And texture can be expressed as it is. That is, the holes 320 formed in the base film 300 are formed at uniform intervals in a small but uniform area, so that they can be recognized as a whole shape when viewed from the naked eye. Since the holes 320 are formed through the base film 300, the gold foil 200 is exposed through the holes 320, so that the color and the rough texture of the gold foil 200 can be expressed intact.

Here, in step S200, the predetermined area may be a graphic or text form. For example, as shown in FIG. 2, when the hole 320 is formed in the shape of 'I love you', the light is not refracted through the base film 300, And the rough texture of the gold foil 200 can be expressed as it is. That is, when the base film 300 and the gold foil 200 are adhered to each other, the image printed on the image layer 310 and the shape formed by the plurality of holes can be distinguished from each other due to the difference in color and texture due to the holes 320 have. Therefore, the method of manufacturing a dual-image gold leaf print according to an embodiment of the present invention is advantageous in that the shape formed by the holes 320 can give a feeling different from the image printed on the base film 300, Images can be represented.

At this time, step S200 may form a hole 320 by irradiating the base film 300 with a laser beam on the opposite side of the surface on which the image layer 310 is formed. When the laser beam is irradiated to the base film 300, the base film 300 melts around the light spot of the laser beam, so that only the hole 320 may not be neatly punctured. Thus, step S200 may irradiate the laser beam on the opposite side of the surface on which the image layer 310 of the base film 300 is formed. Since the surface on which the image layer 310 of the base film 300 is formed corresponds to the surface where the printed image is seen from the front side, a neat aesthetic feeling of the gold leaf print can be maintained by irradiating the laser beam on the opposite surface.

FIG. 3 is a view showing an aluminum plate 100 on which a cavity 110 is formed in a method of manufacturing a gold leaf print having a dual image according to an embodiment. In step S300, the coating of the aluminum plate 100 may be oxidized to form the void 110. [ The aluminum plate 100 may be oxidized by placing the positive and negative electrodes using a rectifier in an electrolytic solution. In this process, the aluminum plate is oxidized and an oxide film is formed. At the + electrode, oxygen is generated and oxidized. At this time, since aluminum combines with oxygen to form holes, aluminum dissolves, so that fine voids 110 are formed on the aluminum surface, as shown in FIG. That is, in step S300, the coating of the aluminum plate 100 may be oxidized by using a rectifier containing hydrochloric acid, thereby forming the voids 110. Step S300 corresponds to a pretreatment process for more firmly adhering the gold foil 200 to the aluminum plate 100 as an etching process.

In step S400, the gold foil 200 may be adhered to the aluminum plate 100 on which the void 110 is formed in step S300. Since the cavity 110 is formed at step S300 so that the surface of the aluminum plate 100 is formed with a rugged fine bend, the gold foil 200 can be more easily bonded. The aluminum plate 100 and the gold foil 200 may be bonded together using a metal adhesive, preferably an epoxy adhesive. Here, the gold foil 200 may be a plate formed by spreading pure gold thinly. Preferably, the purity of the gold foil 200 may be 99.9%.

4 is a view showing a state in which the aluminum plate 100, the gold foil 200 and the base film 300 are bonded in the method of manufacturing a gold foil print having a dual image according to an embodiment. Step S500 is a step of bonding the gold foil 200 adhered to the aluminum plate 100 in the short period S400 and the opposite surface of the surface on which the image layer 310 of the base film 300 having the hole 320 formed in step S200 is formed can do. More specifically, in operation S500, a laser beam is radiated from the aluminum plate 100 to melt one surface of the base film 300 contacting the gold foil 200, and the bubbles 332 generated in the molten base film 300 are melted, The gold foil 200 and the base film 300 can be adhered to each other using a high pressure generated by the high pressure. Referring to FIG. 4A, in step S500, the aluminum plate 100 to which the gold foil 200 is bonded and the base film 300 are overlapped and fixed. Thereafter, a pulse laser beam is irradiated to contact the gold foil 200 The melted portion 330 corresponding to one surface of the base film 300 can be melted. At this time, the melting point of the base film 300 should be lower than that of the aluminum plate 100 and the gold foil 200. Referring to FIG. 4B, a small bubble 332 may be generated as heat generated by the laser beam is conducted to melt the melted portion 330 in the base film 300. 4C, the anchoring effect may be generated by pushing the molten plastic into the fine gaps or intervals of the surface of the gold foil 200 at a high pressure generated by the rapid expansion of the bubbles 332. In addition, a Van der Waals force may occur which is caused by adherence of the molten plastic to the surface of the oxidation film of the gold foil 200. Accordingly, in step S500, the gold foil 200 and the base film 300 can be firmly adhered to each other through the anchoring effect corresponding to the mechanical bonding and the Van der Waals force corresponding to the physical bonding.

On the other hand, since aluminum has a high reflectance, it is preferable to irradiate a laser beam from the aluminum plate 100 rather than the base film 300. When an aluminum plate 100 is irradiated with a laser beam, a part of the adhesive applied to the aluminum plate 100 is melted and an anchoring effect may occur between the aluminum plate 100 and the gold foil 200. Particularly, since the oxidation film is formed on the aluminum plate 100 in step S300, the aluminum plate 100 and the gold foil 200 can be more firmly adhered to each other due to the Van der Waals force generated by the adhesion to the oxidation film surface.

At this time, in step S500, the laser beam spot size may be 0.02 mm. The smaller the spot size of the laser beam, the smaller the size of the fused portion 330 where the base film 300 is melted, so that the aesthetics of the gold leaf print can be avoided. In particular, since the base film 300 is easily peeled off at the corner portion, step S500 is a step of irradiating a laser beam to a region corresponding to a corner portion of the gold foil 200 to improve adhesion with the base film 300, I can not hurt the overall aesthetics. In addition, depending on the embodiment, step S500 may firmly bond the aluminum plate 100, the gold foil 200 and the base film 300 on the entire surface by irradiating the laser beam at regular intervals.

In step S600, the coating layer 400 may be formed on the surface of the base film 300 on which the image layer 310 is formed. Depending on the embodiment, step S600 may apply a transparent lacquer to the surface of the base film 300 on which the image layer 310 is formed. However, if the coating layer 400 is formed on the surface of the base film 300 on which the image layer 310 is formed to protect the image layer 310, the method of forming the coating layer 400 is not limited to the above embodiment Do not.

5 is a view showing a configuration of a gold leaf print according to another embodiment. The gold leaf print according to another embodiment can be produced by the above-described steps S100 to S600 of the method of manufacturing a gold leaf print having a dual image. As shown in FIG. 5, the gold foil print may include an aluminum plate 100, a gold foil 200, a base film 300, and a coating layer 400. The aluminum plate 100 may be an aluminum plate 100 having a gap 110 formed by oxidizing the coating in step S300. The gold foil 200 may be a plate attached to the aluminum plate 100 in step S400. The base film 300 may include an image layer 310 generated in step S100 and a hole 320 formed in step S200. The aluminum plate 100, the gold foil 200, and the base film 300 may be adhered to each other in step S500. The coating layer 400 may be formed on the surface on which the image layer 310 is formed in step S600.

As described above, the method of manufacturing a gold foil print having a dual image according to the disclosure and the gold foil printing method, wherein the gold foil is adhered to a film printed with an image, and a hole is formed in a part of the film, So that it is possible to express another image in addition to the image printed on the film. The method of manufacturing a gold foil print having a dual image according to the disclosure and a gold foil printing method include a phenomenon in which a film is peeled from a gold foil by bonding an aluminum foil, a gold foil and a film using a laser, The durability of the gold leaf printed matter can be remarkably improved.

100: aluminum plate
110: air gap
200: Gold leaf
300: base film
310: Image layer
320: hole
330:
332: Bubble
400: Coating layer
S100: a step of printing an image with UV (Ultra Violet) ink on one side of a base film to generate an image layer
S200: forming a hole through the base film at predetermined intervals in a predetermined region by using a laser on the base film on which the image layer is formed in step S100
S300: Step of oxidizing the coating of the aluminum plate to form voids
S400: Step of bonding the gold foil to the aluminum plate on which the gap is formed in Step S300
S500: a step of bonding the gold foil adhered to the aluminum plate in step S400 and the opposite surface of the surface on which the image layer of the base film having the hole is formed in step S200
S600: forming a coating layer on the surface of the base film on which the image layer is formed

Claims (11)

A method for manufacturing a gold leaf print using a gold foil adhered to a front portion of a plaque comprising an aluminum plate as a base plate,
(1) printing an image with UV (Ultra Violet) ink on one side of a base film to produce an image layer;
(2) forming a hole through the base film at predetermined intervals in a predetermined region by using a laser on the base film that has generated the image layer in the step (1);
(3) oxidizing the coating of the aluminum plate to form voids;
(4) bonding the gold foil to the aluminum plate having the void in the step (3);
(5) bonding the gold foil adhering to the aluminum plate in the step (4) to the opposite surface of the base film on which the image layer is formed in the step (2); And
(6) forming a coating layer on a surface of the base film on which the image layer is formed.
2. The method of claim 1, wherein the step (1)
Characterized in that white is printed so that Yellow is 20%, Magenta is 10% and Cyan is 4% in the entire halftone dots.
3. The method of claim 2, wherein the hole of step (2)
Wherein the diameter is from 0.3 mm to 1 mm.
4. The method of claim 3, wherein step (2)
Characterized in that the predetermined area is a figure or text shape.
5. The method of claim 4, wherein step (2)
Characterized in that a hole is formed by irradiating a laser beam on the opposite side of the surface of the base film on which the image layer is formed.
6. The method of claim 5, wherein step (3)
Wherein the film of the aluminum plate is oxidized using a rectifier containing hydrochloric acid.
7. The method of claim 6, wherein step (5)
Characterized in that the aluminum foil is irradiated with a laser beam to fuse one surface of the base film contacting with the gold foil and to adhere using a high pressure generated by bubbles generated in the melted base film, A method of producing a printed matter.
8. The method of claim 7, wherein step (5)
Wherein the pulsed laser beam is irradiated with a pulsed laser beam.
The method as claimed in claim 8,
Wherein the melting point is lower than the aluminum plate and the gold foil.
10. The method of claim 9, wherein step (5)
Wherein the laser beam has a light spot size of 0.02 mm.
A gold foil print produced by a method of manufacturing a gold foil print having the dual image of any one of claims 1 to 10.

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