KR20180076670A - Manufacturing apparatus and method for 3-D security pattern to prevent forgery - Google Patents

Abstract

The present invention relates to an apparatus and a method for manufacturing a 3-dimensional security pattern for preventing forgery and, more specifically, to an apparatus and a method for processing a 3-dimensional fine pattern on a surface or at an inner side to prevent forgery. The apparatus for manufacturing a 3-dimensional security pattern for preventing forgery according to the present invention comprises a laser system, a stage, and a galvanoscanner. The present invention can secure forgery prevention in which copy or damage is difficult by marking a surface with different depths or cutting a pattern inside.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a three-dimensional security pattern production apparatus and method for preventing forgery,

The present invention relates to an apparatus and method for producing a three-dimensional security pattern for preventing falsification, and more particularly, to a manufacturing apparatus and method for processing three-dimensional fine patterns on a surface or inside thereof will be.

To prevent forgery of the original, stick a mark or sticker with a security pattern. At this time, the mark or sticker for preventing counterfeiting is mostly formed in the plane of micro-unit thickness. In this case, copying or duplication is possible, which makes it difficult to prevent forgery.

Registration No. 10-1397959 (registered on May 15, 2014)

The present invention is intended to solve the above problems. The present invention relates to a three-dimensional security pattern production apparatus and method for preventing forgery, which is difficult to duplicate or undermine by marking different depths on a surface or engraving a pattern on the inside based on processing depth control through laser focusing and intensity control And to provide the above objects.

An apparatus for fabricating a 3D security pattern for preventing falsification according to the present invention includes a laser system, a stage, and a galvanometer scanner to form a three-dimensional pattern on a workpiece. The laser system includes an optical system capable of focusing the output of the laser so as to process the material with a laser. The stage is movable up and down by stacking the work so that the work can be moved up and down. The galvano scanner can move the laser of the laser system right and left and back and forth.

According to an aspect of the present invention, a method for fabricating a 3D security pattern for anti-counterfeiting includes a data separation step, a material fixing step, a focusing step, a planar processing step, and a vertical processing step. The data separation step separates data of a shape modeled by a 3D security pattern into layers. In the material fixing step, a transparent material is fixed to a stage capable of moving up and down. The focusing step focuses the laser to a desired point inside the material using a laser system having an optical system capable of focusing and focusing the output of the laser. In the planarizing step, the laser beam of the laser system is moved left and right and back and forth using a galvanometer scanner capable of moving left and right and back and forth, thereby processing the separated layer in the data separation step. The vertical machining step moves the stage up and down so that the focal point of the laser can move in the outward direction of the workpiece so that the planar machining step is performed in each and every layer separated in the data separation step.

According to another aspect of the present invention, a method for fabricating a three-dimensional security pattern for anti-counterfeiting includes a data separation step, a material fixing step, a focusing step, a planar processing step, and a vertical processing step. The data separating step separates data of a shape modeling a 3D security pattern into layers. In the material fixing step, an opaque material is fixed to a stage capable of moving up and down. The focusing step focuses the laser at a desired point on the surface of the work using a laser system having an optical system capable of focusing and outputting the laser. In the planarizing step, the laser beam of the laser system is moved left and right and back and forth using a galvanometer scanner capable of moving left and right and back and forth, thereby processing the separated layer in the data separation step. The vertical machining step moves the stage up and down so that the focal point of the laser can move inwardly of the workpiece such that the planar machining step is performed in each and every layer separated in the data separation step.

Also. The method for fabricating a 3D security pattern for preventing forgery preferably further includes a filling step of filling a processed surface of the material with a filler to coat the material.

According to the present invention, it is possible to engrave a pattern having different depths on the surface, and furthermore, to engrave a pattern inside the surface rather than on the surface. Therefore, it is possible to make a very wide variety of patterns, it is hard to damage, and it is hard to judge by general equipment or the naked eye.

Therefore, it is possible to manufacture a wider range of patterns, and it is difficult to grasp the characteristics of the pattern by the human vision because it includes not only the plane pattern but also the height and the height in the authenticity determination.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of an apparatus for fabricating a three-dimensional security pattern for anti-
FIG. 2 is a conceptual diagram in which a security pattern is formed on a surface and inside of a work using the embodiment of FIG. 1;
FIG. 3 shows an example of application of a security pattern made using the embodiment of FIG. 1,
Dimensional shape data of a security pattern made using the embodiment of FIG.

Conventional anti-counterfeiting technologies rely on planar elements because they mark the surface of the product or make stickers. In this case, it is easy to imitate because it can be easily measured by general equipment. In order to improve the three-dimensional security pattern fabrication apparatus for anti-falsification according to the present invention, a pattern with deep information that can not be easily measured is generally formed.

1 to 4, an embodiment of an apparatus for fabricating a 3D security pattern for preventing falsification according to the present invention will be described.

An apparatus for fabricating a 3D security pattern for anti-counterfeiting according to the present invention includes a laser system 10, a galvanometer scanner 2, and a stage 30.

The laser system 10 is provided with an optical system capable of focusing with the output of the laser 11 so that the material 1 can be processed by the laser 11.

The galvano scanner 20 can be finely adjusted by a computer to move the laser 11 of the laser system 10 right and left and back and forth.

The stage 30 is movable up and down by placing the work 1 so that the work 1 can be moved up and down.

A process of fabricating a three-dimensional security pattern for preventing forgery on the work 1 using the embodiment shown in FIG. 1 will be described.

A data separation step, a material fixing step, a focusing step, a planar machining step and a vertical machining step when a three-dimensional security pattern is embedded in a transparent material.

The data separation step separates the data modeled by the 3D security pattern into layers. That is, first, the modeling data of the three-dimensional security pattern shape to be buried in the inside is divided into the respective layers using a slicing program so that the laser can expose the layered data. At this time, the shape of the 3D security pattern may be a point, a line shape, or a shape having a volume.

The material fixing step fixes the work 1 to the stage 30.

The focusing step adjusts the origin of the laser system 10 so that the focus of the laser is located at a desired point inside the work 1 using the laser system 10. [

The planarizing step moves back and forth along the xy path obtained by extracting the focus of the laser 11 of the laser system 10 from the lowest layer on the xy plane using the galvanometer scanner 20, do.

The vertical machining step is a step of vertically moving the stage 30 in the z-axis direction so that the focal point of the laser can move in the outward direction of the work 1 so that the plane machining step is performed in all the layers separated in the data separation step .

If the horizontal machining step and the vertical machining step are repeatedly performed for each layer, a three-dimensional shape is machined inside the work 1. At this time, the xy axis information is processed by the galvano scanner 20, and the z axis information is processed by the stage 30. In general, exposure starts from the bottom to rise up to avoid marking on the z-axis path during exposure.

A data separation step, a material fixing step, a focusing step and a planar machining step, a vertical machining step and a filling step, when the 3D security pattern is formed on the surface of the opaque material.

The data separation step separates data of a shape modeling a three-dimensional security pattern to be formed on the surface of the work 1, like the transparent material.

The material fixing step fixes the work (1) to the stage (30).

The focusing step focuses the laser 11 at a desired point on the surface of the work 1 using a laser system.

The planarizing step is performed by moving the laser focus according to the xy position information obtained from the modeling data on the surface of the work 1 by using the galvanometer scanner 20.

The vertical processing step moves the stage 30 so that the focal point of the laser can move inward of the workpiece, thereby processing the interior of the workpiece 1. [

The filling step is performed by filling the processed surface of the work (1) with a filler. This is to protect the surface of the material.

FIG. 2 is a view of a surface of a glass container processed using the embodiment of FIG. Even if the surface is not plane, it is possible to control the z value through the modeling as long as the shape information of the surface is available. Therefore, the inside of the transparent container can be processed as well as the surface. Through these embodiments, a 3D security pattern can be formed on the surface as well as on the inside as shown in FIG.

FIG. 4 is a three-dimensional shape information of a security pattern processed with different depth values, and shows a deep pattern edge and a shallow inner pattern.

In this embodiment, the type of the beam irradiated by the laser is not limited to a specific beam, and an optical system for collecting the beam may be included.

1: Material 10: Laser system
11: Laser 20: Galvano Scanner
30: stage

Claims (4)

A laser system having an optical system capable of focusing and outputting the laser so as to process a material with a laser;
A stage capable of lifting and lowering the work so that the work can be moved up and down,
And a galvanometer scanner capable of moving the laser of the laser system in the left and right direction and the back and forth direction to form a three-dimensional pattern on the material. A data separating step of separating data of a shape modeling a three-dimensional security pattern into layers,
A material fixing step of fixing a transparent material to a stage capable of moving up and down,
A focusing step of focusing the laser at a desired point inside the material using a laser system having an optical system capable of focusing and outputting the laser,
A plane processing step of moving the focal point of the laser of the laser system left and right and back and forth using a galvano scanner capable of moving left and right and back and forth so as to process the separated layer in the data separation step,
And a vertical machining step of vertically moving the stage so that the focal point of the laser moves in the outward direction of the workpiece so that the plane machining step is performed in each of the layers separated in the data separation step How to make a 3D security pattern to prevent forgery. A data separating step of separating data of a shape modeling a three-dimensional security pattern into layers,
A material fixing step of fixing an opaque material to a stage capable of moving vertically,
A focusing step of focusing the laser at a desired point on a surface of the work using a laser system having an optical system capable of focusing and outputting a laser,
A plane processing step of moving the focal point of the laser of the laser system left and right and back and forth using a galvano scanner capable of moving left and right and back and forth so as to process the separated layer in the data separation step,
And a vertical machining step of vertically moving the stage so that the focal point of the laser can move inward of the workpiece so that the plane machining step is performed in each of the layers separated in the data separation step How to make a 3D security pattern to prevent forgery. The method of claim 3,
Further comprising a filling step of filling a processed surface of the material with a filler to coat the material.

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