WO2017031804A1

WO2017031804A1 - Random multi-color three-dimensional physical anti-counterfeit marker, manufacturing device and manufacturing method

Info

Publication number: WO2017031804A1
Application number: PCT/CN2015/090470
Authority: WO
Inventors: 郑国义
Original assignee: 郑国义
Priority date: 2015-08-25
Filing date: 2015-09-23
Publication date: 2017-03-02
Also published as: CN105150711A

Abstract

Provided are a random multi-color three-dimensional physical anti-counterfeit marker, manufacturing device and manufacturing method. The manufacturing method comprises: designing, via a computer, a pattern of a marker grain and a laser operation trajectory; placing a thin sheet member on a processing pillow block, and producing a marker grain having a three-dimensional hollowed-out marker by irradiating the sheet member with a focused high-energy laser pulse light; and randomly distributing the marker grain in a transparent adhesive or a surface of an object to be marked, so as to form a random multi-color three-dimensional physical anti-counterfeit marker. The method reduces raw material costs and manufacturing processing steps, thus improving manufacturing efficiency, and decreasing the amount of waste materials and liquids to better protect the environment.

Description

Random colorful three-dimensional physical anti-counterfeiting mark, making device and manufacturing method thereof

Technical field

The invention relates to the field of identifying anti-counterfeiting, in particular to a random colorful three-dimensional physical anti-counterfeiting mark, a manufacturing device and a manufacturing method thereof.

Background technique

In the prior art, the raw material for etching the micro-embossed marker generally uses silicon. Although the chemical property is stable, the cost is too high, which is disadvantageous for large-scale production. On the other hand, the etching step is cumbersome, and some of the processes still require manual operation, and the construction period is long. Furthermore, the etching process requires the use of a large amount of chemical reagents, and there are many waste water, waste liquid, and waste materials, which are not conducive to environmental protection production requirements.

Summary of the invention

The object of the present invention is to provide a random colorful three-dimensional physical anti-counterfeiting mark, a manufacturing device and a manufacturing method thereof, aiming at reducing the cost of raw materials, reducing the production process, reducing the "three wastes" emissions, and improving the production efficiency.

In order to achieve the above object, the first technical solution provided by the present invention provides: a method for manufacturing a random colorful three-dimensional physical security mark, comprising the following steps:

(1) The pattern of the computer designed marker particles, according to the pattern of the marker particles, simulates the corresponding laser running track;

(2)

The sheet material is placed on the processing axis, the laser light source is turned on to emit laser light, and the optical system is focused and outputted to form a focused high-energy pulse spot;

(3) The pulse spot is irradiated to the sheet material, and according to the laser running track of the simulation design in step (1) Row movement to generate marker particles having a three-dimensional hollow mark;

(4) The marker particles are randomly scattered on the surface of the transparent colloid or the object to be marked to form a random and colorful three-dimensional physical security mark.

In the above step (2), the laser light emitted by the laser light source passes through the beam expander, the polarized light path, and the optical path polymerization device to form a focused high-energy pulse spot.

In the above step (3), after the sheet material is in contact with the high-energy pulse spot, the contact position of the sheet material reaches the melting point, and the hole is formed by sputtering, and a series of sizes and depths are formed on the corresponding position on the sheet material according to the running track of the laser. A three-dimensional hollow mark, a three-dimensional hollow mark on the sheet material and the sheet material constitutes a marker particle, and the size and depth of the hole depend on the size of the laser spot and the irradiation time.

In the above step (4), an indefinite number of marker particles are randomly distributed on the surface of the transparent colloid or the object to be marked, and the different marker particles have different hollow mark structures, colors or distribution angles, and constitute a unique anti-counterfeiting mark.

Preferably, the marker particles have a diameter of from 0.6 mm to 1 mm and have different color attributes.

The second technical solution provided by the present invention is: a random colorful three-dimensional physical security mark formed by one or more marker particles dispersed on a surface of a transparent colloid or a marker, the marker particles being composed of a sheet material and a sheet The three-dimensional hollow mark on the material is composed, and the label particles are randomly distributed on the surface of the transparent colloid or the object to be marked, and the different label particles have different hollow mark structures, colors or distribution angles.

The three-dimensional hollow mark having different numbers and arrangement paths on each of the marker particles has a difference in diameter and depth size of the three-dimensional hollow mark.

The marker particles have a diameter of from 0.6 mm to 1 mm and have different color attributes.

The third technical solution provided by the present invention is: a device for fabricating a random colorful three-dimensional physical security mark, comprising a laser, a beam expander, a polarized light path and an optical path polymerization device, and a processing axis table is arranged under the optical path polymerization device, in processing A sheet material is placed on the pillow table, wherein the laser light emitted by the laser source passes through the beam expander, the polarized light path and the optical path polymerization device to form a focused high-energy pulse spot image. Shot on the sheet material, moving according to the simulated design of the laser trajectory to generate marker particles with three-dimensional hollow marks.

Preferably, when the high-energy pulse spot is in contact with the sheet material, the contact position of the sheet material reaches the melting point, and the hole is formed by sputtering, and a series of three-dimensional hollowings of different sizes and depths are formed on the sheet material according to the running track of the laser material. The three-dimensional hollow mark on the mark, sheet material and sheet material constitutes a marker particle, and the size and depth of the hole depend on the size of the laser spot and the irradiation time.

The invention not only reduces the cost of raw materials, reduces the production process, reduces the discharge of waste water, waste liquid and waste, but also achieves high environmental protection requirements through the use of a high-concentration laser fine processing method. The marker particles have a variety of recognizability such as naked eye visibility, pleochroism, etc., which are scattered on the surface of the transparent colloid or the object to be marked, forming a random and colorful three-dimensional physical security mark, and having excellent anti-counterfeiting which is difficult to imitate and copy. effect.

The invention will be more apparent from the following description, taken in conjunction with the accompanying drawings.

detailed description

FIG. 1 is a schematic diagram of a process method according to an embodiment of the present invention.

FIG. 2 is a schematic diagram of a device for making a random colorful three-dimensional physical anti-counterfeiting mark according to an embodiment of the present invention.

detailed description

Embodiments of the present invention will now be described with reference to the drawings, in which like reference numerals represent like elements.

The embodiment of the present invention first provides a method for manufacturing a random colorful three-dimensional physical security mark. Referring to FIG. 1, the method includes the following steps:

S001 computer design marker particle pattern, according to the pattern of the marker particles, simulate the corresponding laser running track;

S002 places the sheet material on the processing axis, and the laser source turns on the laser, passing through the optical system. Focusing the output to form a focused high-energy pulse spot;

S003 pulse spot is irradiated to the sheet material, and is moved according to the simulated laser running track in step S001 to generate marker particles having a three-dimensional hollow mark;

S004 randomly distributes the marker particles on the surface of the transparent colloid or the object to be marked to form a random and colorful three-dimensional physical security mark.

Wherein, in the above step S002, the laser light emitted by the laser light source passes through the beam expander, the polarization path and the optical path polymerization device to form a focused high-energy pulse spot.

Wherein, in the above step S003, after the sheet material is in contact with the high-energy pulse spot, the contact position of the sheet material reaches the melting point, and the hole is formed by sputtering, and a series of sizes and depths are formed on the corresponding position on the sheet material according to the running track of the laser. A three-dimensional hollow mark, a three-dimensional hollow mark on the sheet material and the sheet material constitutes a marker particle, and the size and depth of the hole depend on the size of the laser spot and the irradiation time.

Wherein, in the above step S004, an indefinite number of marker particles are randomly distributed on the surface of the transparent colloid or the object to be marked, and different marker particles have different hollow mark structures, colors or distribution angles, and constitute a unique anti-counterfeiting mark. After attaching this system to the surface of the product, the interior, and the outer packaging, each product has a unique anti-counterfeiting mark corresponding to it. The micro-particles are convenient for the naked eye to directly query the system information according to its arrangement to distinguish the authenticity, and can play different roles according to different needs.

In this embodiment, the marker particles have a diameter of 0.6 mm to 1 mm and have different color attributes.

Embodiments of the present invention provide a random colorful three-dimensional physical security mark, which is formed by dispersing one or more marker particles on a surface of a transparent colloid or a marker, the marker particles being three-dimensionally formed on the sheet material and the sheet material. The hollow mark is composed, and the label particles are randomly distributed on the surface of the transparent colloid or the object to be marked, and the different label particles have different hollow mark structures, colors or distribution angles.

In this embodiment, each of the marker particles has a three-dimensional hollow mark with a different number and arrangement path, and the diameter and depth of the three-dimensional hollow mark have different sizes. The marker particles have a diameter of from 0.6 mm to 1 mm and have different color attributes.

Finally, the embodiment of the present invention further provides a device for fabricating a random colorful three-dimensional physical anti-counterfeiting mark. Referring to FIG. 2, the invention comprises a laser, a beam expander, a polarized light path and an optical path polymerization device, and a processing axis table is arranged below the optical path polymerization device. a sheet material is placed on the processing axis, wherein the laser light emitted by the laser source passes through the beam expander, the polarization path and the optical path polymerization device to form a focused high-energy pulse spot to illuminate the sheet material, and the laser trajectory according to the simulation design Movement is performed to generate marker particles having a three-dimensional hollow mark.

In this embodiment, when the high-energy pulse spot is in contact with the sheet material, the contact position of the sheet material reaches the melting point, and the hole is formed by sputtering. According to the running track of the laser, a series of different sizes and depths are formed on the corresponding position on the sheet material. The three-dimensional hollow mark, the three-dimensional hollow mark on the sheet material and the sheet material constitutes a marker particle, and the size and depth of the hole depend on the size of the laser spot and the irradiation time.

According to the above, the present invention not only reduces the cost of raw materials, reduces the production process, reduces the discharge of waste water, waste liquid and waste, but also achieves high environmental protection requirements by using a high-concentration laser fine processing method. Moreover, the processed marker particles have various recognizable degrees such as naked eye visibility and pleochroism, and are scattered on the surface of the transparent colloid or the object to be marked, forming a random and colorful three-dimensional physical security mark, which is excellent and difficult to imitate. And copy the anti-counterfeiting effect.

The above is only the preferred embodiment of the present invention, and the scope of the present invention is not limited thereto, and the equivalent changes made by the scope of the present invention remain within the scope of the present invention.

Claims

A method for manufacturing a random colorful three-dimensional physical security mark, comprising the steps of:

(1) The pattern of the computer designed marker particles, according to the pattern of the marker particles, simulates the corresponding laser running track;

(2) placing the sheet material on the processing axis table, the laser light source is turned on to emit the laser light, and is focused and output after passing through the optical system to form a focused high-energy pulse spot;

(3) the pulse spot is irradiated to the sheet material, and is moved according to the simulated laser running track in the step (1) to generate the marker particles having the three-dimensional hollow mark;

(4) The marker particles are randomly scattered on the surface of the transparent colloid or the object to be marked to form a random and colorful three-dimensional physical security mark.
The method for fabricating a random colorful three-dimensional physical anti-counterfeit mark according to claim 1, wherein in step (2), the laser light emitted by the laser light source is focused by a beam expander, a polarized light path, and an optical path polymerization device. High energy pulse spot.
The method for fabricating a random colorful three-dimensional physical security mark according to claim 1, wherein in the step (3), after the sheet material is in contact with the high-energy pulse spot, the contact position of the sheet material reaches the melting point and is sputtered. Forming a hole, according to the running track of the laser, a series of three-dimensional hollow marks of different sizes and depths are formed on the corresponding positions on the sheet material, and the three-dimensional hollow mark on the sheet material and the sheet material constitutes a marker particle, and the size and depth of the hole are determined. The size of the laser spot and the illumination time.
The method for fabricating a random colorful three-dimensional physical security mark according to claim 1, wherein in step (4), an indefinite number of marker particles are randomly distributed on the surface of the transparent colloid or the object to be marked, different The marker particles have different hollow marking structures, colors or distribution angles. Form a security mark.
The method for fabricating a random colorful three-dimensional physical security mark according to claim 1 or claim 3, wherein the marker particles have a diameter of 0.6 mm to 1 mm and have different color attributes.
A random colorful three-dimensional physical security mark characterized in that: one or more marker particles are dispersed on a surface of a transparent colloid or a mark, and the mark particles are composed of a three-dimensional hollow mark on a sheet material and a sheet material. The marker particles are randomly distributed on the surface of the transparent colloid or the object to be marked, and the different marker particles have different hollow mark structure, color or distribution angle.
The random colorful three-dimensional physical security mark according to claim 6, wherein each of the marker particles has a three-dimensional hollow mark with a different number and arrangement path, and the diameter and the depth of the three-dimensional hollow mark have different sizes.
A random colorful three-dimensional physical security mark according to claim 6 or claim 7, wherein the marker particles have a diameter of 0.6 mm to 1 mm and have different color attributes.
A device for manufacturing a random and colorful three-dimensional physical anti-counterfeiting mark, comprising: a laser, a beam expander, a polarized light path and an optical path polymerization device, wherein a processing axis table is arranged below the optical path polymerization device, and a sheet material is placed on the processing axis table, The laser light emitted by the laser source passes through the beam expander, the polarized light path and the optical path polymerization device to form a focused high-energy pulse spot to be irradiated on the sheet material, and is moved according to the simulated design laser running track to generate a mark with a three-dimensional hollow mark. Particles.
A device for fabricating a random colorful three-dimensional physical security mark according to claim 9, The feature is that when the high-energy pulse spot is in contact with the sheet material, the contact position of the sheet material reaches the melting point, and the hole is formed by sputtering, and a series of three-dimensional hollowings of different sizes and depths are formed on the corresponding position on the sheet material according to the running track of the laser material. The three-dimensional hollow mark on the mark, sheet material and sheet material constitutes a marker particle, and the size and depth of the hole depend on the size of the laser spot and the irradiation time.