KR101995215B1 - manufacturing method of holographic hot stamping foil - Google Patents

Abstract

The present invention provides a manufacturing method of a holographic hot stamping foil. The method comprises the steps of: preparing a base film (11); coating a release layer (12) for separating a film on one surface of the base film (11); coating an embossable coloring layer (13) on the top surface of the release layer (12); embossing a hologram protrusion pattern (14) on the top surface of the coloring layer (13); depositing a metal thin film (15) on the top surface of the embossed hologram protrusion pattern (14); coating a digital printing adhering layer (16) on the top surface of the metal thin film (15) to manufacture a holographic hot stamping foil (10); preparing an adhesive material (21); digital printing any character or shape on one surface of the adhesive material (21) to manufacture a printing sheet (20) having a printing layer (22) formed thereon; and passing the digital printing adhering layer (16) of the holographic hot stamping foil (10) and the printing layer (22) of the printing sheet (20) through a rubber roller (1) while facing each other, and applying heat and pressure to transfer the hologram protrusion pattern (14) of the holographic hot stamping foil (10) to any character or shape forming the printing layer (22) in the printing sheet (20), thereby forming a transfer layer (30). Accordingly, the present invention minimizes stamping defects of embossing molds to maximize productivity, and fundamentally prevents a device from being damaged during a transfer process.

Description

Manufacturing method of holographic hot stamping foil [

The present invention relates to a method of manufacturing a holographic hot stamping foil, and more particularly, to a holographic hot stamping foil which can express various shapes very conveniently without using a separate embossing die corresponding to the shape or letter to be implemented. And to a method of manufacturing the same.

A stamping foil is obtained by depositing aluminum foil and a metal foil on one side of a thin film. A stamping foil embossed as a hologram pattern by thermal fusion is called a holographic hot stamping foil.

Such an holographic hot stamping foil can be classified into an up-down stamping method in which convex and concave patterns are transferred by the heat and pressure of the embossing die embossed with letters and patterns, On-stamping method in which the concave / convex patterns are successively transferred by applying a roll-on stamping method.

However, regardless of how the embossed pattern is embossed in the holographic hot stamping foil, the conventional holographic hot stamping foil is basically made of continuous printing and stamping operations on the adherend such as paper, plastic or fiber So that productivity is remarkably deteriorated.

In the case of the conventional holographic hot stamping foil, various types of embossing dies or embossed rubber rollers must be prepared in order to express detailed and complex patterns, and embossed molds or embossed rubber rollers The productivity may be lowered in that the embossing operation must be carried out separately.

In addition, there is a problem that if the embossing is not carried out appropriately at the part required in the work process, it immediately leads to the defect. In the embossing process, the laminating transferring device and the digital printing device There is also a phenomenon that damage is caused.

Korea Patent Publication No. 2005-0120436

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the prior art, and it is an object of the present invention to provide a method of embossing, in which embossing work does not need to be carried out according to a printed shape so that defects can be minimized and productivity can be maximized, And a method for manufacturing a graphic hot stamping foil very easily.

In order to achieve this object, the present invention provides a method of manufacturing a semiconductor device, comprising: preparing a base film (11); Applying a release layer (12) for separating the film to one side of the base film (11); Applying an embossable coloring layer (13) on an upper surface of the release layer (12); Embossing the hologram concave-convex pattern 14 on the upper surface of the colored layer 13; Depositing a metal thin film (15) on the upper surface of the embossed hologram uneven pattern (14); Forming a holographic hot stamping foil (10) by applying a digital printing adhesive layer (16) to an upper surface of the metal foil (15); Preparing an adherend (21); A step of digitally printing an arbitrary letter or shape on one surface of the adhering material 21 to produce a printing sheet 20 on which the printing layer 22 is formed; The adhesive layer 16 for digital printing of the holographic hot stamping foil 10 and the print layer 22 of the printing sheet 20 are passed between the rubber rollers 1 while being opposed to each other while applying heat and pressure, And transferring the hologram concave-convex pattern 14 of the foil 10 to an arbitrary letter or shape of the print layer 22 in the print sheet 20 to form the transfer layer 30. [ .

The release layer 12 comprises an over-printable release layer; When the holographic irregular pattern 14 of the holographic hot stamping foil 10 is transferred to the printing layer 22 of the printing sheet 20 and the transfer layer 30 is formed on the transfer layer 30, The additional printing layer 40 may be formed by digital printing.

According to the present invention, the hologram irregular pattern can be transferred only to the upper surface of the printing layer formed on the adhering material by simply joining the foil and the adhering material with heat and pressure without using a separate embossing mold, It is possible to maximize the productivity by minimizing the defective embossing of the embossing mold and also to prevent the damage of the apparatus in the transferring process.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1A is a schematic laminate construction view of a holographic hot stamping foil according to the present invention. FIG.
Fig. 1B is a schematic laminate construction view of a printing sheet according to the present invention. Fig.
Fig. 1C is a schematic laminate construction view in which a transfer layer is formed on a printing sheet according to the present invention. Fig.
2A is a schematic structural view of a printing sheet according to the present invention;
FIG. 2B is a schematic view of a schematic configuration in which a transfer layer is formed on the printing sheet of FIG. 2A. FIG.
FIGS. 3A and 3B are schematic views showing different transfer processes according to the present invention; FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the technical features of the present invention, A detailed description thereof will be omitted.

The present invention relates to a method of making a holographic hot stamping foil, basically comprising the steps of making a holographic hot stamping foil (10), making a printed sheet (20), and forming a holographic hot stamping foil And transferring the concave-convex pattern by laminating the printed sheets 20 together. Each of these steps will be discussed in detail.

The holographic hot stamping foil 10 disclosed in FIG. 1A can be manufactured through the following steps.

First, the base film 11 is prepared. The base film 11 is a part to be a base material in the holographic hot stamping foil 10, and is made of a conventional PET film, and preferably has a thickness in the range of 6 to 38 mu m.

When the base film 11 is prepared, the release layer 12 is coated on one surface thereof. The release primer layer 12 may be a conventional oily urethane resin, an aqueous polyurethane resin, an oily wax, or an aqueous wax as a means for easily separating a film when heat and pressure are applied in a transfer process, which will be described later .

When the releasing layer 12 is applied, the embossable coloring layer 13 is applied on the upper surface thereof. The embossable lacquer layer 13 is a colored primer layer for embossing the hologram concave-convex pattern, and can be made of a conventional acrylic or urethane thermoplastic and thermosetting resin.

When the embossable coloring layer 13 is applied to one surface of the base film 11, the hologram concave-convex pattern 14 is embossed on the upper surface thereof. The embossing of the hologram concave / convex pattern can be achieved by any one of hard embossing method and soft embossing method widely known in the related art. When the metal master or the UV film master heated to the predetermined temperature is pressed against the embossable coloring layer 13, the hologram uneven pattern 14 is formed.

The hologram concavo-convex pattern 14 formed on the embossable coloring layer 13 is independent of the shape of the digital print layer 22 to be described later. That is, the hologram irregular pattern may be formed in any shape.

When the hologram concave / convex pattern 14 is embossed on the upper surface of the embossable coloring layer 13, the metal thin film 15 is deposited on the upper surface of the embossed concave / convex pattern 14. The metal thin film 15 is a means for reflecting the hologram concave / convex pattern 14, and the deposition of the metal thin film can be performed by a method well known in the related art.

When the metal thin film 15 is deposited on the upper surface of the hologram uneven pattern 14, the digital printing adhesive layer 16 is applied to the upper surface of the metal thin film 15. The digital printing adhesive layer 16 is for adhering to the ink used in a digital printer and is excellent in adhesion to each of the toners of the digital printer, the toner of the general laser printer, and the ink of the silk screen, Need to be excellent.

Further, it is preferable that the adhesive layer does not have adhesiveness to paper or film, and in the transfer process described later, it is preferable that the adhesive layer is melted and adhered to the adherend in a pressure range of about 4 kgf and a temperature range of 120 to 200 캜. To this end, the digital print adhesive layer proposes a case where the ratio of the modified vinyl resin and silica is 6: 4 to 7: 3.

When the digital printing adhesive layer 16 is applied to the upper surface of the metal thin film 15, the production of the holographic hot stamping foil 10 according to the present invention having the laminated structure as shown in Fig. 1A is completed.

The printing sheet 20 according to the present invention as shown in FIG. 1B can be prepared as follows, which is a separate step from the production of such a holographic hot stamping foil 10. It will be appreciated that the printed sheet 20 may be fabricated prior to or at the same time as the holographic hot stamping foil 10 through a separate process.

First, the adherend 21 is prepared. The adherend 21 is a part of the final product which becomes a base material, and may be made of a paper or a synthetic resin film or sheet. When the adherend 21 is made of paper, it may be made of a sticky structure having an adhesive on its back surface.

When the adhering material 21 is prepared, the print layer 22 is formed by digitally printing an arbitrary letter or shape on one surface of the adherend 21. There is no limitation to the letter or shape of the digital print layer 22, and any letter may be used.

When the digital printing layer 22 is formed on one side of the adherend 21, the production of the printing sheet 20 according to the present invention is completed. The printing sheet 20 may be of a continuous structure having an individual structure having a predetermined width and a predetermined length, as well as being wound on a roll. 2A shows an example of a print sheet as a separate structure in which a print layer made of a letter is formed on paper as an adherend.

The adhesive layer 16 of the holographic hot stamping foil 10 and the printing layer 22 of the printing sheet 20 are opposed to each other in the state of being opposed to each other. And passes through a pair of rubber rollers shown in the drawing, and is heat-pressed and lapped.

Each of Figures 3a and 3b shows a roll-to-roll laminating and roll-to-sheet laminating method for lamination of the holographic hot stamping foil 10 and the printing sheet 20 according to the present invention, an example of laminating is disclosed.

The rubber roller (not shown) provided in each of FIGS. 3A and 3B is a member which passes through a roller between the rollers in a state in which a stamper (metal mold) for embossing is mounted on one surface of the roller like roll on stamping Instead of embossing under pressure, the holographic hot stamping foil 10 and the sheets 20 to be laminated are simply pressed and operated only as means for transferring heat.

When heat is transferred in a state where each of the holographic hot stamping foil 10 and the printing sheet 20 is pressed, the base film 11 of the holographic hot stamping foil 10 is separated as shown in FIG. The transfer layer 30 is formed on the upper surface of the print layer 22 of the recording layer 20 by the hologram irregular pattern 14.

At this time, the digital printing adhesive layer 16 is excellent in adhesion to the ink of the digital printer, but has almost no adhesion to paper or a synthetic resin film used as the adherend 21, so that the hologram irregular pattern 14 is formed on the printing layer 22 ) Of the recording medium.

Fig. 2b shows an example of a finished printed sheet as a separate structure disclosed in Fig. 2a, which is completed in the manner of Fig. 3b. As can be seen from FIG. 2B, when a digital printing layer is formed on the adherend with arbitrary characters, the hologram irregular pattern is transferred only to the upper surface of the digital printing layer made of arbitrary characters by applying heat and pressure to the holographic hot stamping foil It can be seen that a transfer layer is formed.

That is, if a holographic hot stamping foil for digital printing is laminated on a paper or film surface digitally printed in arbitrary shape or letter with an individual sheet structure or a continuous reel structure, it is not transferred to paper or film at all, The hologram hot stamping foil is transferred only to the upper surface of the printed layer.

In other words, even if arbitrary letters or shapes are printed in black on the adherend, they can be expressed in various colors according to the types of holograms (rainbow hologram, silver ring hologram, 3D effect hologram, CGH hologram, etc.) This is possible.

Accordingly, it is possible to express various shapes in various ways, as well as to minimize the defective rate in the embossing work process, without preparing various kinds of separate embossing dies according to the shape to be expressed on one surface of the adherend, It is possible to prevent the phenomenon of damage.

The present invention is characterized in that a holographic hot stamping foil 10 and a printing sheet 20 are laminated together to form a transfer layer 30 by a hologram irregular pattern 14 on the top surface of a digital printing layer 22 of a printing sheet 20 A separate transfer layer is further formed on the upper surface of the adhering material 21.

That is, if a transfer layer is formed along the characters as shown in FIG. 2B, any shape or letter may be digitally printed on the margin of the adherend 21 on which the transfer layer is not formed (the upper surface of the transfer layer may also be included) A holographic hot stamping foil is formed, and then the holographic hot stamping foil is formed by laminating it with the holographic uneven pattern different from the holographic uneven pattern of the holographic hot stamping foil described above or by forming a separate transfer layer will be.

In this case, a variety of hologram irregular patterns are transferred for each digital print layer every time the transfer is performed, so that a product having a very colorful and colorful hologram image can be manufactured.

In the meantime, the present invention is characterized in that the release layer 11 applied to one surface of the base film 11 is formed of an over-printable release layer, and the protrusive pattern 14 of the holographic hot stamping foil 10 is made of a non- A step of digitally printing an arbitrary shape on the upper surface of the transfer layer 30 to form the additional printing layer 40 is added when the transfer layer 30 is formed on the printing layer 22 of the transfer layer 20. [ I never do that.

The overprintable release layer itself functions as a release layer to ensure easy separation from the base film 11 in the transfer step of the hologram concavo-convex pattern, and in addition, the transferred hologram concave-convex pattern And has a function of enabling separate digital printing on the upper surface of the transfer layer 30. Such a printability releasing layer may be constituted by diluting an aqueous polyurethane resin and an aqueous wax in the range of 9: 1 to 8: 2.

The additional printing layer may be formed using various types of digital printers as well as monochromatic printing such as black as well as color printing such as natural color. This additional printing layer enables the holographic hot stamp foil to be applied to a wider variety of applications.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It will be apparent that the present invention can be practiced with added features.

10: holographic hot stamping foil 20: printed sheet
30: transfer layer 40: additional printing layer

Claims (2)

Preparing a base film (11);
Applying a release layer (12) for separating the film to one side of the base film (11);
Applying an embossable coloring layer (13) on an upper surface of the release layer (12);
Embossing the hologram concave-convex pattern 14 on the upper surface of the colored layer 13;
Depositing a metal thin film (15) on the upper surface of the embossed hologram uneven pattern (14);
Forming a holographic hot stamping foil (10) by applying a digital printing adhesive layer (16) to an upper surface of the metal foil (15);
Preparing an adherend (21);
A step of digitally printing an arbitrary letter or shape on one surface of the adhering material 21 to produce a printing sheet 20 on which the printing layer 22 is formed;
The adhesive layer 16 for digital printing of the holographic hot stamping foil 10 and the print layer 22 of the printing sheet 20 are passed between the rubber rollers 1 while being opposed to each other while applying heat and pressure, Transferring the hologram concave-convex pattern 14 of the foil 10 to an arbitrary letter or shape of the print layer 22 in the print sheet 20 to form the transfer layer 30;
A method of making a holographic hot stamping foil comprising: The method according to claim 1,
The release layer 12 comprises an over-printable release layer; When the holographic irregular pattern 14 of the holographic hot stamping foil 10 is transferred to the printing layer 22 of the printing sheet 20 and the transfer layer 30 is formed on the transfer layer 30, To form an additional printing layer (40) is added; ≪ / RTI >

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