KR20120077526A - A method for forming muti-direction latent images on metal product and metal product formed with the multi-direction latent images thereby - Google Patents

Abstract

According to the present invention, a groove is formed on a surface of a latent mold made of alloy tool steel by using a laser processing machine, and at the same time, the inner surface of each of the grooves is divided into as many divided surfaces as the number of latent image patterns, and the respective divided surfaces. Forming different latent images in step (step 1), repeating step 1 to form a plurality of grooves in which the latent images are formed continuously, each latent image formed on the divided surface facing the same direction among the plurality of grooves Manufacturing a multi-directional latent image mold such that the combination forms a latent image pattern (step 2); and the latent image having a shape corresponding to the groove and the latent image by injecting the multi-directional latent image mold onto the surface of the metal product Since there is provided a method of forming a multi-directional latent image on a metal product including the step of forming a protrusion (step 3), the surface of the metal product may not only be improved in appearance but also in gold. To authenticity identification and counterfeit / tamper-proof means of the product is able to utilize.

Description

A method for forming muti-direction latent images on metal product and metal product formed with the multi-direction latent images according to the present invention.

The present invention implements a fine and sophisticated multi-directional latent image on the surface of a metal product, so that the multi-directional latent image can be utilized not only to improve the appearance of the metal product surface but also to identify the authenticity of the metal product and to prevent forgery / modulation. The present invention relates to a metal product having a multidirectional latent image formed thereon.

Recently, in order to protect the company's brand and to prevent illegal copying of the product, a genuine product mark and a sticker hologram are attached to the metal product, but the genuine product mark can be easily forged.

In addition, in the case of a sticker hologram, there is an advantage that can be used universally regardless of the material of the adherend, such as paper, plastic, metal, ceramic, etc., but since the PET film layer-release layer-hologram support layer-hologram layer-adhesive layer is sequentially stacked However, expensive equipment and facilities are required. In addition, the long-term use of the product may cause the hologram to become poor and easily peel off or be damaged from the adherend.

On the other hand, there is also a technology that gives a latent effect to coins for counterfeiting and tampering, the Republic of Korea Patent Publication No. 1998-021489 (published on November 21, 1998, hereinafter referred to as "quotation 1") Disclosed is a method of manufacturing a mold for two-way latent image coins in which two patterns are formed on a specific part of the pattern, but only one type of pattern is visible and the other type is not visible depending on the viewing direction.

In Citation 1, a serrated acid and a valley are formed on a gypsum plate of an arbitrary shape, and then a latent pattern of different shapes on each side of the serrated mountain by a method of carving by a engraver. After carving, and duplicating this to the resin plate, and then using a known shredder on the basis of the resin plate replicating the latent image pattern, the latent image pattern formed on both sides of the acid, bone and acid on a predetermined portion of the mold is reduced.

If the mold manufactured by the above method is used, the surface of metal products such as coins, medals, tokens, etc. may be embossed by the press-embossing method to express the pattern for preventing forgery and high quality, but in water Because the latent image is implemented, the latent mold manufacturing time and the pattern reproducibility are inferior, and the latent image that can be implemented is also limited in two directions.

In particular, the technique of Citation 1 is, "① forming a hill and a valley on the plaster plate with a milling machine, ② ② latent flaw by water carving on both sides of the mountain ③ replicate with a resin plate ④ shrunk into a latent mold using a shredder ⑤ latent mold Since the process must be a five-step manufacturing process called "injection to metal products", the manufacturing process is complicated, there is a problem that the processing time increases and the manufacturing cost increases accordingly to engrave the latent image into pieces.

On the other hand, Korean Laid-Open Patent Publication No. 1998-021490 (published on June 6, 1998, hereinafter referred to as "quotation 2") refers to a multi-directional latent image coin which shows three or more kinds of latent images in three or more directions. to provide.

In Citation 2, a hemispherical groove is continuously formed on a flat alloy hole by a milling machine, and a flat metal plate is pressed by an alloy hole having a groove to form a flat metal plate with a hemispherical protrusion corresponding to the hemispherical groove. Let's do it.

Subsequently, the surface of each hemispherical protrusion formed on the flat metal plate is divided at a predetermined angle, so that one kind of pattern can be continuously seen in each direction of each divided surface. Lastly, the latent image pattern flat metal plate manufactured by carving is reduced and sculpted in a predetermined portion of the mold for casting a casting machine by a miniaturized engraving machine, thereby producing a latent image coin engraved with the latent image pattern.

However, such a manufacturing method also has to determine the dimensions in consideration of the reduction ratio by the shredding machine, so the pattern reproducibility is reduced, and as a result of different patterns, many trial and error must be experienced.

In addition, since the latent image patterns are processed adjacent to each other on the surface of the latent mold groove, the latent image patterns need to overlap each other at the boundary between different latent images or to express various latent images on the small surface area of the latent projections. Since the pattern itself disappears or becomes smaller, it is difficult to reproduce a vivid latent image, and there are problems in that the carving and the machining method are limited to finely and precisely implement three or more kinds of latent images.

In addition, the manufacturing step is "① forming grooves in the alloy hole with a milling machine, ② press the alloy hole formed in the grooves on a flat metal plate ③ latent image formed by each piece of hemispherical projection of the flat metal plate, ④ shrink the flat metal plate with the latent image pattern Squeezing the latent mold for casting the powder by means of 5 steps of manufacturing process called "pressing the latent mold into coins", the manufacturing process is complicated, and the processing time is increased because the latent image is carved into pieces. There is still a problem of rising.

The present invention can maximize the miniaturization of the latent pattern and the latent image compared to the latent mold produced by a conventional water sculpture or mechanical sculpture, thereby enabling it to be used as an authenticity identification method in terms of protecting a brand of a product. It is an object of the present invention to provide a method for forming a multidirectional latent image on a metal product and thereby a metal product having a multidirectional latent image formed thereon.

In addition, the present invention, by forming a multi-directional latent image directly on the latent image mold using a laser processing machine, without having to go through the intermediate manufacturing process, the manufacturing process is very simple compared to the conventional, multi-directional that can reduce the manufacturing cost It is an object of the present invention to provide a method for forming a latent image on a metal product and thereby a metal product having a multidirectional latent image formed thereon.

According to one embodiment of the present invention, at the same time forming the groove on the surface of the latent mold of the alloy tool steel by using a laser processing machine, the inner surface of each groove is partitioned by the number of divided surfaces by the number of latent image patterns, Forming different latent images on each divided surface (step 1), and repeating the first step to continuously form a plurality of grooves in which the latent images are formed, wherein the divided surfaces face the same direction among the plurality of grooves; Manufacturing a multi-directional latent image mold such that each combination of latent images formed forms a latent image pattern; and injecting the multi-directional latent image mold onto a surface of a metal product, the shape corresponding to the groove and the latent image Provided is a method of forming a multi-directional latent image on a metal product, comprising the step (3) of forming a latent image projection having a.

According to another embodiment of the present invention, at the same time to form a groove on the surface of the latent mold of the alloy hole by using a laser processing machine, the inner surface of each groove is used to separate the number of latent image patterns by using the laser processing machine Forming a latent image separation wall portion, and forming different latent images on respective divided surfaces of the recesses separated by the latent image separation wall portion (step 1); Manufacturing a multi-directional latent image mold such that a combination of each latent image formed on a dividing surface facing the same direction among the plurality of grooves forms one latent image pattern, the second groove being continuously formed; A latent image projection having a shape corresponding to the groove, the latent image separation wall portion, and the latent image is formed by injecting a multi-directional latent image mold onto the surface of the metal product. And forming the latent image projections by the shape of the latent image separation wall of the latent image mold such that the plurality of latent images formed on the latent image projections are separated from each other by being separated from each other. A method of forming a multidirectional latent image on a metal product is provided.

On the other hand, after the second step in the above embodiments, it is preferable to heat-treat the latent mold to a temperature range of 750 ~ 850 ℃, to form a hard chromium plating layer on the surface of the latent mold.

In addition, the recess of the latent mold may be formed in any one of pitch, hemispherical, conical, conical, triangular, square, or hexagonal.

According to the present invention, there is also provided a metal product in which a multidirectional latent image is formed by the above-described method.

According to the present invention, unlike the prior art had to manufacture the latent mold through a number of steps, by using a laser processing machine to form a latent image pattern directly on the latent mold of the alloy tool steel, significantly reducing the manufacturing time of the latent mold compared to the conventional As a result, the mold manufacturing process can be simplified.

In addition, according to the present invention, not only the reproducibility of the latent image pattern but also three or more kinds of complicated latent image patterns that cannot be expressed in existing pieces or machine pieces can be expressed finely and precisely. Therefore, the grooves formed in the latent mold are not only basic shapes such as pitch, hemispherical, square, and cone, but also high-quality coin, commemorative coin, and medal by applying the company's own symbols, characters, and year as latent images. It can be applied to not only coin products, but also high-priced metal labels, to show the authenticity of products and prevent counterfeiting.

Furthermore, according to the present invention, the latent image is separated with a predetermined gap so that the plurality of latent images formed on the latent image are separated from each other, so that the latent image patterns are reproduced according to the direction of observation. On the contrary, excellent latent image reproducibility can be realized.

1 is a plan view showing a first embodiment of a multi-directional latent mold formed in accordance with the present invention;
2 is a cross-sectional view of FIG.
3 is a perspective view of a metal product in which the latent latent mold of FIG. 1 is sanded to form a multidirectional latent image;
4 is a schematic view of a process of separating the latent protrusions shown in FIG.
Figure 5 is a plan view showing a second embodiment of a multi-directional latent mold manufactured in accordance with the present invention.
6 is a cross-sectional view taken along the line EE of FIG. 5 as viewed in the FF direction;
7 is a perspective view showing a cross-sectional state taken along the line EE of FIG.
FIG. 8 is a perspective view of a metal product in which a latent mold of FIG. 5 is sanded to form a multidirectional latent image; FIG.

Hereinafter, a process of forming the multidirectional latent image according to the present invention on a metal product will be described in detail with reference to the drawings. 1 and 2 show a first embodiment of a multidirectional latent image mold made in accordance with the present invention.

In the present invention, as shown in Fig. 1, a plurality of grooves 2 are formed on the surface of the latent mold 1 made of an alloy tool steel for cold die, using a known laser processing machine (not shown).

When the groove 2 is formed on the surface of the latent mold 1, Nd: YAG (neodymium-doped yttrium aluminum garnet; Nd: Y ₃ Al ₅ O ₁₂ based on a computer-programmed latent image degree) _, Wavelength: 1064 nm) The high power energy (40W) of the laser is irradiated to the surface of the latent mold 1, and the sample stage of the laser processing machine equipped with the latent mold 1 is moved to the x, y and z axes of the Cartesian coordinate system. Grooves 2 are formed on the surface of the latent mold 1 as it is transferred.

At the same time as the grooves 2 are formed by using a laser processing machine, the inner surface 3 of each of the grooves 2 is divided into divided planes as many as the number of latent image patterns to be reproduced, and different latent images on each divided surface. Form (step 1).

FIG. 1 shows that the inner surface 3 of the groove 2 is partitioned into four divided surfaces A, B, C and D with respect to the virtual latent image dividing line 4. In Fig. 1, four different kinds of latent images are formed on the divided surfaces A, B, C, and D of the groove 2 in the clockwise direction.

Next, the combination of the respective latent images formed on the dividing surface (for example, the dividing surface A) facing the same direction among the plurality of grooves 2 while continuously performing the first step using a laser processing machine. A multidirectional latent mold is produced to form one latent lace pattern as a whole (step 2).

In the above, the term "lattice pattern" is used to mean a whole image reproduced when the latent mold or a product manufactured by the latent mold is observed at different angles and directions, and "latent image" The term is used to mean a partial small image which forms a whole "latent image".

Therefore, in the embodiment of Fig. 1, according to the latent image mold 1, four types of latent image patterns are reproduced as a whole depending on the angle to be observed.

Finally, the latent image mold 1 formed as described above is pressed against the surface of the target metal product 5 to form a multidirectional latent image.

FIG. 3 shows a latent image projection having latent images A ', B', C ', and D' respectively corresponding to latent images formed on each of the divided surfaces A, B, C, and D of the groove 2; 6 shows a metal product 5 in which (step 3) is formed.

As described above, by forming a multi-directional latent image pattern directly on the latent mold 1 made of alloy tool steel using a laser processing machine, the manufacturing time of the latent mold can be significantly shortened and the mold manufacturing process can be simplified.

In addition, since the latent image pattern is formed by using a laser processing machine, it becomes possible to express the fine and precise representation of the latent image pattern as well as three or more kinds of complex latent image patterns that cannot be expressed in existing pieces or machine pieces.

On the other hand, in order to further distinguish the latent image effects observed according to the direction and angle of observing the product, the latent image separation cutter 8 so that the multi-directional latent images formed on the latent image projections 6 are separated from each other by their respective latent images. It will also be possible to separate the latent image (6) by.

4 shows that the latent image 6 is pressurized from the upper side by the latent image separation cutter 8 along the latent image dividing line 7 and spaced apart from each other while forming a gap 10 into a plurality of small latent image protrusions 9. The process of separation is shown.

At this time, each of the separated latent image projections 9 has only one type of latent image, and each latent image is clearly separated by the gap 10, thereby preventing overlapping at the boundary between adjacent latent images. The distinctiveness of latent patterns is significantly increased according to the direction of observation.

5 to 8 show a second embodiment according to the present invention.

In the embodiment shown in Figs. 5 to 7, the groove 12 is continuously formed on the surface of the latent mold 11 made of alloy tool steel using a laser processing machine, and the inner surface 13 of each groove 12 is formed. ) Forms simultaneously the latent image separation wall portion 14 using a laser processing machine such that " separated " by the number of latent image patterns.

On the other hand, in the present specification, the term "separation" used in the second embodiment is used to mean that they are spaced apart from each other with a gap.

In addition, different latent images are formed on each of the divided surfaces A, B, C, and D of the recesses 12 separated by the latent image separation wall 14 using a laser processing machine.

While repeating the above process, a plurality of recesses 12 in which the latent images are formed are continuously formed, as shown in FIG. 7.

Fig. 7 shows a multi-directional latent image mold 11 manufactured such that a combination of each latent image formed on the divided surfaces facing the same direction among the plurality of grooves 12 forms one latent image pattern.

When the latent image mold 11 shown in Fig. 7 is injected onto the surface 15 of the metal product, the groove 12, the latent image separation wall 14, and the latent image are wound on the surface of the metal product 15 as shown in Fig. 8. A latent image projection 16 having a corresponding shape is formed.

8, each of the latent image projections 16 in which a plurality of latent images A ', B', C ', and D' are formed by the shape of the latent image separating wall portion 14 is provided. It is shown separated by four latent projections spaced apart from each other with a gap 17 corresponding to the thickness.

Accordingly, the plurality of latent images A ', B', C ', and D' formed on the latent image protrusions 16 are separated from each other, so that four types of latent image patterns may be observed when the metal product 5 is observed as a whole. Since the reproduction, the latent image pattern is more clearly distinguished and reproduced according to the direction of observation.

On the other hand, in the above embodiments, as the material of the latent mold, it is possible to use 11 types of STD (type of high alloy forging tool steel).

Prepared as described above, the latent mold (1,11) is preferably vacuum heat treatment for 1 hour in the temperature range of 750 ~ 850 ℃ in order to improve the durability, such as impact resistance and wear resistance. In addition, the surface of the latent image mold (1, 11) may be preferably subjected to surface polishing to remove residual scale and improve surface glossiness after heat treatment.

In addition, it is also preferable to form a hard chromium plating layer of 5 ~ 10㎛ on the surface of the latent mold (1,11) by using a solution of chromic anhydride (CrO ₃ ) to improve wear resistance. When the thickness of the plating layer is 5 μm or less, abrasion resistance improvement effect is inferior, and when the thickness is 10 μm or more, a problem occurs that the adhesion between the base metal and the plating layer is decreased.

In the above-described embodiments, only the case where the hemispherical grooves 2 and 12 are formed is described as an embodiment, but the shape of the grooves 2 and 12 is pitch, hemispherical, conical, conical, In addition to the shape of a square, triangle, hexagon, etc., it is also possible to apply the company's own symbols, characters, year, etc. as a latent image.

If the grooves 2 are formed in a pitch shape, it is preferable that the grooves 2 are formed so that the distance between the sawtooth and the peaks is 0.15 to 0.40 mm. In the case of 0.15 mm or less, as the number of grooves per unit area increases, the adjacent angle between the sawtooth-shaped hill and the valley becomes sharp, so that the formation of the latent lace pattern is not easy. In addition, in the case of 0.40 mm or more, the number of grooves that can form the latent image pattern decreases, so the latent image effect is reduced.

Moreover, it is preferable that the height of an acid is 0.05-0.20 mm. In the case of 0.05mm or less, the height of the mountain is low, so it is not easy to form the latent image, and the latent effect is also insignificant. On the other hand, if the height is 0.20mm or more, the protruding part of the latent image is sharp and acts as a stress concentration part when implementing the latent pattern on the metal product by the injecting method, which reduces wear resistance and impact resistance, resulting in shortening the life of the latent mold.

1,11: latent mold 2,12: groove
3,13: inside 4: latent image dividing line
14: latent image separation wall part 5, 15: metal product
6,9,16: Latent projection 7: Latent division
8: latent image separation cutter 10, 17: clearance

Claims (8)

A groove is formed on the surface of the latent image mold made of alloy tool steel by using a laser processing machine, and the inner surface of each of the grooves is divided into as many dividing surfaces as the number of latent image patterns, and different latent images are formed on the divided surfaces. Forming step (step 1),
By repeating step 1, a plurality of recesses in which the latent images are formed are continuously formed, and the combination of the respective latent images formed on the divided surfaces facing the same direction among the plurality of recesses forms one latent image pattern. Manufacturing a mold (step 2), and
Forming a latent image on the metal product by injecting the multi-directional latent image mold onto the surface of the metal product to form a latent projection having a shape corresponding to the groove and the latent image (step 3). How to. The method according to claim 1,
After the second step, the latent mold is heat-treated at a temperature range of 750 ~ 850 ℃,
And forming a hard chromium plating layer on the surface of the latent mold. The method according to claim 2,
The recess of the latent mold is a method of forming a multi-directional latent image on a metal product, characterized in that formed in the shape of any one of pitch, hemispherical, conical, cone, triangle, square, or hexagon. The metal product in which the multidirectional latent image was formed by the method of any one of Claims 1-3. At the same time as forming a groove on the surface of the latent mold of the alloy tool steel by using a laser processing machine, a wall for separating the latent image is formed by using the laser processing machine so that the inner surface of each groove is separated by the number of latent patterns. Forming different latent images on each of the divided surfaces of the grooves separated by the latent image separation wall (step 1),
By repeating step 1, a plurality of recesses in which the latent images are formed are continuously formed, and the combination of the respective latent images formed on the divided surfaces facing the same direction among the plurality of recesses forms one latent image pattern. Manufacturing a mold (second step), and
Injecting the multi-directional latent image mold onto the surface of the metal product to form a latent image projection having a shape corresponding to the groove, the latent image separation wall portion, and the latent image (step 3),
The latent image is formed on the metal product, characterized in that the latent image projections are separated by the shape of the latent image separation wall of the latent image mold so that the plurality of latent images formed on the latent image are separated from each other laterally. How to. The method according to claim 5,
After the second step, the latent mold is heat-treated at a temperature range of 750 ~ 850 ℃,
And forming a hard chromium plating layer on the surface of the latent mold. The method of claim 6,
The recess of the latent mold is a method of forming a multi-directional latent image on a metal product, characterized in that formed in the shape of any one of pitch, hemispherical, conical, cone, triangle, square, or hexagon. The metal product in which the multidirectional latent image was formed by the method of any one of Claims 5-7.

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