KR102105081B1 - Pattern label made of various thicknesses using focal length - Google Patents

Abstract

The present invention relates to a pattern label capable of being manufactured in various thicknesses by using a focal length. An anti-counterfeiting label having a three-dimensional pattern is manufactured by using a lens array, a transparent sheet and a pattern sheet, wherein the three-dimensional pattern is formed by using light reflected after light transmission so that a slim label may be obtained. The pattern label includes: a lens array in which semi-spherical lenses having a size of 20-100 micrometers are formed; a transparent pattern sheet which has a pattern printed to have the same pitch as the lenses of the lens array; and a transparent sheet which is disposed between the upper side of the pattern sheet and the lower side of the lens array. Particularly, the transparent sheet is formed by disposing the pattern within the focal length of the lens and forming a reflective layer for reflecting light at the bottom of the pattern sheet.

Description

Pattern label made of various thicknesses using focal length}

In the present invention, in manufacturing a forgery prevention label of a three-dimensional pattern using a lens array, a transparent sheet, and a pattern sheet, a three-dimensional pattern is formed with reflected light by transmitting light, thereby using various focal lengths that can be made slim. It relates to a pattern label that can be produced in thickness.

The present invention is to produce a label that distinguishes the authenticity of a product by producing a slim label and simultaneously making it invisible to the naked eye so that the designed pattern shape is visible only when light is shined.

The three-dimensional pattern capable of three-dimensional expression regardless of the place is produced in various ways, but as shown in FIG. 1, the lens array 10 is formed of an array of finely sized lenses 11 and the lens array 10. The pattern sheet 20 on which the pattern 21 enlarged through the formed lens 11 is printed, and the pattern 21 of the pattern sheet 20 is positioned at the lens focal length f1 of the lens array 10 The transparent sheet 30 is used.

That is, since the focal length (f1) is adjusted using the transparent sheet 30 so that the pattern 21 of the pattern sheet 20 can be positioned at the lens focal length (f1) of the lens array 10, the thickness The slimming is limited, and the larger the diameter of the lens 11 is, the easier it is to express a three-dimensional pattern, but the focal length f1 is longer, making it difficult to produce labels with a thickness of several μm to 20 μm. 11) The smaller the diameter, the shorter the focal length (f1), which makes it easy to slim, but causes a problem that is almost invisible to the eye.

The shorter the focal length f1 of the lens 11 is, the easier it is to slim, but there is a limit to the expression of the three-dimensional pattern, and the longer the focal length f1 of the lens 11 is disadvantageous to ultra-thinning, but the three-dimensional pattern is easy to express. There are advantages, but labels of various thicknesses such as 50㎛, 100㎛, and 150㎛ can be manufactured, but since the thickness of the attachment to the label can be thick, it should be possible to manufacture in the form of an ultra-thin film with a thickness of several ㎛ to 20㎛. .

Patent registration 10-0938990 (2010.01.20. Registration) Patent registration No. 10-1472921 (Registered on Dec. 09, 2014) Patent registration 10-0971465 (Registration on July 14, 2010)

In the implementation of the three-dimensional pattern label, the present invention is intended to solve a problem that the label is not slimmed due to the focal length of the lens array. The lens array is made large and the pattern sheet is positioned inside the focal length. The reflective layer is formed on the bottom surface of the lens, so that light passing through the lens array and the transparent sheet is reflected from the reflective layer, thereby realizing a three-dimensional pattern so that slimming is possible.

The present invention is provided with a lens array in which a hemispherical lens having a diameter of 20 to 100 µm is formed, a transparent pattern sheet in which the lens and the pitch of the lens array are uniformly printed, and the upper side of the pattern sheet A transparent sheet is installed between the lower sides of the lens array, and the transparent sheet is formed by placing a pattern inside the focal length of the lens and forming a reflective layer that reflects light to the bottom surface of the pattern sheet, thereby forming a pattern within the focal length of the lens. Even if positioned, the light passing through the lens and the transparent sheet and the pattern sheet is reflected from the reflective layer, so that the pattern is positioned at the focal length, thereby displaying an enlarged three-dimensional pattern.

The present invention increases the lens diameter of the lens array necessary for the realization of the three-dimensional pattern while thinning the thickness of the transparent sheet so that the pattern of the pattern sheet is positioned inside the focal length of the lens while reflecting light to the bottom of the pattern sheet. By forming the reflective layer, light passing through the lens is reflected from the reflective layer to display a pattern in a shade, so that a slim for realizing a three-dimensional pattern can be achieved.

In the present invention, the light toward the lens array is sharper as the light of the strong illuminance is made, and the transparent sheet has a smaller width than the focal length of the lens, so that the slimming is achieved.

In the implementation of the three-dimensional pattern, the present invention allows the pattern of the transparent sheet to be positioned at a position shorter than the focal length of the lens, while forming the lens array and the reflective layer that reflects light passing through the transparent sheet on the bottom of the transparent pattern sheet. By reflecting the light reflected from the reflective layer so that the pattern can be positioned at the focal length of the lens, the enlarged three-dimensional pattern can be expressed through the lens array, and the thickness of the transparent sheet can be made thin. Since it disappears, a label having a thickness of several µm to 20 µm can be produced.

The present invention can produce a label that distinguishes the authenticity of a product by producing a slim label and simultaneously making it invisible to the naked eye so that the designed pattern shape is visible only when light is shined.

In the present invention, it is possible to check the enlarged three-dimensional pattern by using strong light such as cell phone lighting, but when the reflection layer enables reflection of natural light, the fluorescent lamp can also check the color while confirming the enlarged three-dimensional pattern by natural light or the like. Do.

1 is a cross-sectional view of a conventional three-dimensional pattern
Figure 2 is a three-dimensional pattern configuration cross-section of the present invention
Figure 3 is an enlarged cross-sectional view of a conventional three-dimensional pattern configuration
Figure 4 is an enlarged cross-sectional view of the three-dimensional pattern configuration main part of the present invention
5 is an explanatory view of the three-dimensional pattern of the present invention

The present invention is provided with a lens pattern 10 and a transparent pattern sheet 20 on which a pattern 21 is formed with a hemispherical micro-lens 11 having a diameter of 20 to 100 μm, wherein the lens 11 and the pattern 21 are On the other hand, a transparent sheet 50 having a thickness smaller than the focal length f1 of the lens 11 is installed between the lens array 10 and the pattern sheet 20 while the pitch is the same, while the transparent sheet 50 It is made by forming a reflective layer 60 for reflecting light to the bottom surface of the.

In the present invention, the lens 11 of the lens array 10 does not use a conventional micro lens having a size of 1 to 20 μm, but includes a lens array 10 made of a lens 11 having a size of 20 to 100 μm. By doing so, the enlargement of the pattern 21 is made easy.

The pattern 21 of the present invention is to be positioned inside the focal length f1 of the lens 11, and the transparent sheet 30 is not secured and positioned to secure the focal length f1 of the lens 11 as before. , It is possible to reduce the thickness of the transparent sheet 50 by using a thinner transparent sheet 50, and by installing a transparent pattern sheet 20 on its bottom, thereby making it possible to slim.

That is, the present invention is to produce a lens array 10 having a size of the lens 11 of 20 to 100 μm, and then a transparent pattern sheet such that the pattern 21 is positioned at a distance shorter than the focal length f1 of the lens 11 ( By installing 20), the label 100 is manufactured so that the three-dimensional pattern is not visible to the actual eye. After confirming the label 100, strong light is transmitted and reflected from the reflective layer 60 to enlarge the pattern 21 to enlarge the three-dimensional pattern. It is displayed as a pattern.

The larger the diameter of the lens 11 formed in the lens array 10 is, the farther the focal length f1 becomes, and when the pattern 21 is positioned at a distance that does not reach the focal length f1, nothing is visible to the eyes. Since the thickness of the transparent sheet 50 for maintaining the focal length f1 can be made thin, the label 100 can be made slim.

The present invention forms a reflective layer 60 that reflects light to the bottom surface of the transparent pattern sheet 20, but the reflective layer 60 is reflected by the flash of the mobile phone while increasing the reflectance to reflect by fluorescent or natural light.

In the present invention, the lens array 10 and the transparent sheet 50 and the transparent pattern sheet 20 and the reflective layer 60 are sequentially stacked to form a label 100, but the lens 11 of the lens array 10 is By allowing the focal length f1 to be positioned past the pattern sheet 20, the pattern 21 is positioned inside the focal length f1 of the lens 11, so that a three-dimensional pattern is not visible to the eye, but the transparent sheet 50 ), The thickness of the label 100 can be greatly reduced.

In the present invention, since the pattern 21 is located inside the focal length f1 of the lens 11, light shining from the outside penetrates the lens array 10 and the transparent sheet 50 and the transparent pattern sheet 20. After that, since the light is reflected from the reflective layer 60 and illuminates the pattern 21 in shade, the light reflected from the reflective layer 60 is consistent with the focal length f1 of the lens 10 where the pattern 21 is located. Thus, the pattern 21 is enlarged and displayed in a three-dimensional pattern.

That is, in the present invention, since the pattern 21 is positioned at a position shorter than the focal length f1 of the lens 11, the thickness of the transparent sheet 50 is reduced to make the label 100 slim, but with the eyes Since the pattern 21 cannot be identified, the reflective layer 60 is formed on the bottom surface of the pattern sheet 20 so that external light passes through the lens array 10 and the transparent sheet 50 and the pattern sheet 20, and then the reflective layer Next, the pattern 21 reflected from the light 60 is illuminated, which has the same effect as that of the pattern 21 positioned at the focal length f1 of the lens 11, so that a three-dimensional pattern can be expressed. .

In the present invention, since the pattern 21 is located at a position shorter than the focal length f1 of the lens array 10, it is invisible to the eye, but when the strong light shines, it passes through the lens 11 of the lens array 10. After the light passes through the transparent sheet 50 and then passes through the transparent pattern sheet 20, the reflective layer 60 reflects the focal length f1 in the pattern 21, thereby displaying a three-dimensional pattern.

In particular, it is possible to check the hidden three-dimensional pattern simply by using the flash of the smartphone that most people use, so it can be used as a label to check the authenticity of the product regardless of location or time. 10) Since both the pattern 21 and the transparent sheet 50 transmit light, the focal length can be reduced through the reflective layer 60 while various patterns such as company logs and product marks can be put on the reflective layer 60. There are advantages.

In addition, the reflective layer 60 may be manufactured with products such as holograms that have been used in the past to exhibit a more colorful effect.

When the light reflected from the reflective layer 60 does not reflect light, the three-dimensional pattern does not appear, but when the reflection efficiency of the reflective layer 60 is increased, reflection occurs in the reflective layer 60 even by fluorescent or natural light. And thereby a three-dimensional pattern is displayed.

The present invention does not place the pattern 21 on the focal length f1 of the lens 11 formed in a straight line, but labels the pattern 21 by placing the pattern 21 on the focal length f1 formed by being reflected by the reflective layer 60. When strong light is shined on the surface of (100), it is possible to express a three-dimensional pattern.

That is, in the present invention, when the lens array 10 and the pattern sheet 20 are made slim, the pattern 21 is not visible to the eye, but when the light is transmitted through the lens, the lens array 10 and the transparent sheet 50 are visible. And since the pattern sheet 20 is made transparent, shading of the shape of the pattern 21 enlarged by light can be clearly confirmed.

After attaching the lens array 10 and the pattern sheet 20 made to the product to be used, such as plain paper, cloth material, plastic, etc., the pattern 21 formed by shooting light can be checked. And you can check it anywhere.

When the label is made of a material that reflects light well during the production of the label, it is possible to check it even if the light of natural light or fluorescent light shines. The color of the pattern is also prominent depending on the background color and the angle at which the light is reflected. Differentiation is possible.

In the present invention, since the thickness limit of the label 100 is eliminated, it is possible to manufacture a label having a thickness of several tens to several tens of µm, and at the same time, a focal length can be modified according to the design of the lens, so that a label of a thick thickness can be manufactured.

10: lens array 11: lens
20: pattern sheet 21: pattern
30,50: transparent sheet 60: reflective layer
100: label

Claims (5)

It has a lens array 10 formed of an array of hemispherical lenses 11 of 20 ~ 100㎛,
The lens 11 of the lens array 10 and the pitch (pitch) is provided with a transparent pattern sheet 20, the pattern 21 is regularly printed on the upper surface,
A transparent sheet 50 is installed between the upper side of the pattern sheet 20 and the lower side of the lens array 10,
The transparent sheet 50 is placed by placing the pattern 21 inside the focal length f1 of the lens 11,
A reflective layer 60 for reflecting light to the bottom surface of the pattern sheet 20 is formed, but the focal length f1 of the lens 11 passes through the transparent sheet 50 and the transparent pattern sheet 20 to reflect the reflective layer 60. Pattern label that can be produced in various thicknesses by using a focal length, characterized in that it is made to match the pattern 21 printed on the surface of the pattern sheet 20 after being reflected from). delete The pattern label according to claim 1, wherein the light passing through the lens (11) is reflected from the reflective layer (60) and then the pattern (21) is displayed in shades, using a focal length. . The method of claim 1, wherein the focal length (f1) is reduced by using a lens (11), a transparent sheet (50), and a reflective layer (60) to produce various thicknesses using a focal length. Pattern label available. The pattern label according to claim 1, wherein the reflective layer (60) can be manufactured in various thicknesses using a focal length characterized by expressing various designs in a pattern or a hologram by making a pattern or making a hologram.

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