KR20090066826A - A security film including diffractive lens array and a security document using thereof - Google Patents

Abstract

A security film, and a security document using the security film are provided to reduce the thickness to 1/10 level by applying a diffractive lens array part, thereby allowing it to be applied with a form of a thin film. A security film(1) comprises a plurality of diffractive lenses(2) which diffract the incident light; a transparent base part(4) where a diffractive lens array part comprising the arrayed diffractive lenses is formed; an image part(5) which is located at the lower part of the transparent base part and where various pattern or image is formed; and a transparent function part(6) which is located at the lower part of the image part and where the visual additional function is applied.

Description

Security film including diffractive lens array and a security document using

The present invention relates to a security film and a security document using the diffractive lens array unit, and more particularly, to realize the change of the image by the two-dimensional arrangement of the diffractive lenses to realize the color change effect by diffraction The present invention relates to a security film to which a diffractive lens array unit is applicable in a thin film form and a method of manufacturing the same.

The present invention proposes a method of forming a diffractive lens array unit using a lithography method to implement a function of a conventional refractive optical element, and at the same time, to implement an image and color change effect by diffraction appearing at the edge of the diffractive lens and to use it as a security element. do. In addition, by thinning the thickness, which is the biggest advantage of the diffractive optical device, by using a thin film about 1/10 of the existing refractive optical device, it can be applied to various security documents.

Generally, security documents such as bank notes, securities, identification cards, etc. are applied with various security elements to prevent forgery and alteration.

Representative of such a security element is an optical element that can easily identify the authenticity with the naked eye.

Recently, due to the miniaturization of electronic devices, small diffractive optical devices have been developed in the area that cannot be miniaturized by general lenses such as optical devices applied to cameras of mobile phones, and play an important role in the industry. However, most of these diffractive optical elements are not suitable for use as security elements applied to security documents because their size is about several millimeters to several centimeters.

In addition, as photolithography and electron beam lithography technologies are rapidly developed recently, microminiaturization of various devices has been developed mainly in the semiconductor field, and the pattern of the pattern to be manufactured is first formed as a mask, and then exposed to an ultraviolet light source or an electron beam, such as a photoresist. A method of forming a fine pattern on the photosensitive medium has been developed, and through the technique of thermal reflow, it has been possible to manufacture a security element using a fine microlens array portion. Since it is necessary to form a spherical surface of the film had a disadvantage that it is difficult to apply.

After researching and developing such a micro-optical device, the conventional technology applied as a security element. US Pat. No. 4,892,336 uses a lenticular lens, which is a refractive optical element, on one side of a transparent film and a printed pattern on the other side. thread) as a security element.

In addition, US Pat. No. 5,712,731 proposes a method for manufacturing a security element by applying a micro lens array unit with a refractive optical element having a diameter of 50 ~ 250㎛ and a focal length of about 200㎛.

All these techniques use a refractive optical element that must maintain a constant size, so that the overall thickness of the security element is thick, which has a structural disadvantage that is not practical for the application of security documents.

In order to solve this problem, US Patent 20050180020 and Korean Patent Publication No. 10-2006-0121216 disclose a method of using a microlens array unit, which is a non-cylindrical refractive optical element, but this also uses a refractive optical element. There is a limit to reducing the overall thickness, and has the disadvantage of being vulnerable to forgery and alteration by replication and imitation.

In recent years, ultra-precise forgery techniques for forging micro-optical devices such as holograms in the same manner as contact radiation have emerged, and it is urgent to prepare countermeasures, but it has increased social confusion due to the lack of development of differentiated security elements to cope with them. In order to solve these problems, various security element manufacturing methods such as the above method have been developed, but they are vulnerable to counterfeiting and counterfeit because they are vulnerable to duplication and imitation and have insufficient security effects.

Therefore, there is an urgent need for the development of security elements using micro-optical elements that can cope with precise forgery by providing differentiated security that is difficult to implement in the general counterfeiting method.

The present invention has been devised to solve the above problems, and an object of the present invention is to realize the change of the image by the two-dimensional arrangement of the diffractive lenses to realize the color change effect by diffraction, and the thin film form It is to provide a security film and a security document using the diffraction lens array unit that can be applied to.

In order to achieve the above object, the present invention provides a plurality of diffractive lenses (2) for diffracting incident light; A transparent base portion 4 having a diffraction lens array portion 3 in which the diffractive lenses 2 are arranged; An image part 5 positioned below the transparent base part 4 and having various patterns or images formed thereon; And a transparency function unit 6 formed below the image unit 5 and to which a visual additional function is applied.

Or a plurality of diffractive lenses (2) for diffracting incident light; A diffraction lens array section (3) in which the diffraction lenses (2) are arranged; A transparent base portion 4 to which the diffractive lens array portion 3 is attached; An image unit 5 on which various patterns or images are formed; And a transparency function unit 6 formed below the image unit 5 and to which a visual additional function is applied.

Or a plurality of diffractive lenses 2 for diffracting incident light; A transparent base portion 4 having a diffraction lens array portion 3 in which the diffractive lenses 2 are arranged; And a transparency function unit 6 formed below the transparent base unit 4 and to which visual additional functions are applied.

Or a plurality of diffractive lenses (2) for diffracting incident light; A diffraction lens array section (3) in which the diffraction lenses (2) are arranged; A transparent base portion 4 to which the diffractive lens array portion 3 is attached; It may be configured to include; a transparency function unit 6 formed below the transparent base unit 4 and to which visual additional functions are applied.

The diffractive lens 2 has a circular edge and a plurality of edges are formed on the surface in a concentric shape with the edge, and the edge shape may be formed in a shape selected from sawtooth, multi-stepped, stepped, and triangular. Can be.

The diffractive lenses 2 of the diffractive lens array unit 3 are two-dimensionally arranged and may be configured to observe a change in image and color due to diffraction in the image omnidirectional direction.

The image unit 5 may be configured such that an image is separated and viewed at a focal length position of the diffractive lens 2.

In addition, the image unit 5 may be configured to print multiple images.

The transparency function 6 may be formed by forming a semi-transmissive thin film in a material having a high refractive index.

The adhesive part 7 can be constructed by adding an additional security element.

By attaching the security film (1) produced in the above method to the document to make the image not only visible dynamically, but also to configure the security document 10 so that the color change by the diffraction appears.

As described above, the security film to which the diffractive lens array unit is configured has the effect of enlarging and reducing the image by the diffractive lens, forming the dynamic image and effecting the color change through the diffraction phenomenon so that the image change and the color change appear simultaneously according to the viewing direction. Therefore, there is an advantage that provides security different from the existing security elements.

In addition, it is possible to reduce the thickness to less than 1/10 while replacing the existing refractive lens with a diffractive lens is easy to configure a thin film form, which has the advantage that it is easy to apply to a variety of security documents.

The security film 1 to which the diffractive lens array unit of the present invention is applied is basically a transparent substrate on which a diffraction lens 2 for diffracting incident light and a diffraction lens array unit 3 in which a plurality of the diffractive lenses are formed in a two-dimensional array are formed. The image unit 5 is formed below the transparent base portion, and various patterns or images are formed, and the transparent functional portion 6 to which various visual additional functions are applied, apart from the diffraction lens 2, An adhesive portion 7 for attaching the security film of the security document is further configured.

The diffraction lens array portion 3 may be fabricated on the transparent substrate portion 4 to produce the diffraction lens array portion 3 integrally with the transparent substrate portion 4, or the diffraction lens array portion 3 may be separately manufactured. After the transparent substrate portion 4 may be produced by attaching the same purpose and effect of the present invention is the same.

In addition, even if the diffraction lens array portion 3 is formed above or below the transparent base portion 4, the object and effect of the invention are the same.

The diffractive lens 2 has a circular edge and a plurality of edges are formed on the surface in a concentric shape with the edge, and the edge shape may be formed of a sawtooth shape, a multi-stepped shape, a stepped shape, and a triangle. The thickness is about 1 micrometer, and it is produced near a planar shape.

Since the diffractive lens 2 has a circular shape, the image and color change due to diffraction can be observed in all directions of the image side when the image side 5 is looked down through the diffraction lens 2 from the image side. Will be.

The transparent base portion 4 has good light transmittance and can form the diffractive lens array portion 3 by attaching the diffraction lens array portion 3 or by directly embossing, and the lower surface of the transparent base portion 4 can be easily printed. It is preferable to use a material of an acrylic resin system, and the thickness thereof is preferably manufactured similar to the focal length of the diffractive lens 2.

The image portion 5 is preferably formed so that the image can be seen separated according to the focal length of the diffraction lens 2 under the transparent base portion 4 or printed by printing multiple images by a concave printing method or the like.

The transparent function unit 6 is configured to form a semi-transmissive thin film by a method such as vapor deposition of a high refractive index material so that the diffraction effect due to the reflection of light is more pronounced.

In addition to the adhesive, the adhesive part 7 adds another security element (fluorescent paint, infrared sensitive paint, magnetic paint, etc.) exhibiting characteristics such as fluorescence, infrared rays, and magnetic properties to enhance security and identification functions when bonding to a security document. Will be constructed.

When the security film 1 to which the diffractive lens array unit is applied is attached to the security document 10, the image, pattern, characters, etc. appear to be enlarged, reduced, or moved, and at the same time, the effect of color change by diffraction appears. Done.

In addition, unlike a conventional security element using a refractive lens, the diffraction lens (2) can be made as thin as possible thin film and can not be easily replicated, so it can be applied as a security element to various media including documents, cards, and securities. Can be.

In another method, the security film 1 to which the diffractive lens array unit of the present invention is applied includes a diffraction lens 2 which basically diffracts incident light and a diffraction lens array unit 3 in which a plurality of the diffractive lenses are formed in a two-dimensional array. The transparent base portion 4 to be formed and the transparent base portion 6 positioned below the transparent base portion and having various visual additional functions applied to the diffraction lens 2 can be configured.

Of course, the diffraction lens 2 may be processed into the transparent substrate 4 to produce the diffractive lens array 3 integrally with the transparent substrate 4, or the diffractive lens array 3 may be separately manufactured. After the transparency may be produced by attaching to the base portion 4, the object and effect of the present invention is the same.

In addition, even if the diffraction lens array portion 3 is formed above or below the transparent base portion 4, the object and effect of the invention are the same.

At this time, the image unit 5 in which various patterns or images are formed is printed on the security document 10. Security document 10 by confirming the image (8) implemented when viewing the image portion 5 printed on the security document 10 through the security film (1) to which the diffraction lens array is produced in the same way as described above To identify the authenticity of

The features of the present invention will become more apparent from the following detailed description with reference to the accompanying drawings. Prior to this, the terms or words used in this specification and claims are not to be interpreted in a conventional and dictionary sense, and the inventors may appropriately define the concept of terms in order to best explain their invention in the best way possible. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention based on the principle that the present invention.

FIG. 1A illustrates a cross-sectional shape of a general refractive lens, and FIGS. 1B to 1E are cross-sectional views illustrating various diffractive lens shapes, each showing a sawtooth, multi-stepped, stepped, and triangular edge structure.

The diffractive lens 2 in the present invention is an optical element almost close to a plane that can function similarly with a thickness of about 1 μm, unlike a conventional refractive lens that must form a thickness of several tens of μm.

It is preferable that the diameter of the diffraction lens 2 is 30 micrometers or less. In this case, the focal length of the diffractive lens 2 is about 20 to 30 μm, and the thickness of the diffractive lens 2 is preferably approximately λ0 / (n0-1) depending on the design center wavelength and the refractive index of the produced medium. Do. Where λ0 is the design center wavelength and n0 is the refractive index of the medium. For example, when a diffraction lens to be used in the visible light region having a central wavelength of 550 nm is manufactured with PMMA, a general-purpose plastic medium, the thickness of the diffraction lens is about 1.12 mu m because n0 is about 1.49.

The edge shape of the diffractive lens 2 is most preferably in the form of sawtooth as shown in Figure 1b in terms of efficiency, but in view of the difficulty of manufacturing and the efficiency reduction, the present invention can be used as manufactured in Figures 1c to 1e Can achieve the purpose.

The shape of the diffractive lens 2 can be variously implemented by a method such as a lithography method using multiple masks or an electron beam recording method.

2A to 2B are plan views of two-dimensional arrays of diffractive lenses. In terms of utilization of space, a crossover arrangement as shown in FIG. 2B is more preferred. In this case, the two-dimensional array of the diffractive lens 2 is configured such that the image, pattern, characters, etc. of the image portion can be enlarged, reduced or dynamically seen when viewing the image portion of the lower portion of the transparent substrate through the diffraction lens array portion 3. do.

3 is a cross-sectional view of the security film to which the diffractive lens array unit is applied according to an embodiment of the present invention.

First, a diffractive lens array unit 3 having a diameter of 30 μm or less, a thickness of about 1 μm, and a focal length of 20 to 30 μm in two dimensions is arranged as a separate sheet. It adheres to the transparency base material part 4.

At this time, the diffraction lens array unit 3 may be directly formed on the surface of the transparent substrate unit 4 by an embossing method, etc. The object and effect of the present invention may be obtained by manufacturing the diffraction lens array unit 3 as a separate sheet. It is the same as attaching to a transparency base material part.

An image, pattern, or character is printed on the image unit 5 under the transparent substrate 4, but the formed image, pattern, or character is enlarged, reduced or dynamically visible through the diffraction lens array unit 3 do.

The transparency function 6 at the bottom of the image portion 5 forms a semi-transmissive film by coating a high refractive index deposition material to increase the diffraction effect 9 by reflection.

Finally, the adhesive portion 7 at the bottom of the transparent function part 6 is coated with an adhesive or an adhesive to complete a configuration for applying to a security document in the form of a sticker or a thermocompression bonding.

4 is a cross-sectional view of the security film to which the diffractive lens array unit is applied according to another embodiment of the present invention.

First, the transparent base portion 4 is formed on the uppermost side, and under the transparent base portion 4 by a method such as embossing, the diameter is 30 μm or less, the thickness of the shape is about 1 μm, and the focal length is 20 to 30 μm. A diffraction lens array portion 3 consisting of an array of diffraction lenses 2 is formed.

At this time, the transparent base portion 4 is further formed below the diffractive lens array portion 3 and has a higher refractive index than the transparent base portion 4 formed at the uppermost side under the diffraction lens array portion 3 ( 4) is further configured to adjust the focal length.

At this time, the uppermost transparent substrate portion 4 and the transparent substrate portion 4 below the diffractive lens array portion 3 are made of a polymer material composed of different materials, and the difference in refractive index between the two media is preferably about 1.3 to 1.5. Do. If the above refractive index conditions are not satisfied, the focal length of the diffractive lens 2 or the thickness of the transparent base portion 4 located below will be increased.

An image, a pattern, a character, and the like are printed on the image part 5 at the bottom of the transparent base part 4, but the image, pattern, character, etc. 8 formed through the diffractive lens are configured to be enlarged, reduced, or dynamically viewed.

The functional part 6 under the image part 5 is coated with a high refractive index evaporation material to form a transflective film to increase the diffraction effect 9 by reflection.

Finally, the adhesive portion 7 is applied to the adhesive or adhesive to complete the configuration for applying to the security document in the form of stickers or thermocompression bonding.

In this case, since the diffractive lens array unit 3 is located inside the film, the physical and chemical influences of the outside are minimized to obtain the advantage that the durability of the security element is enhanced, and the shape of the security element is duplicated. It's hard to bet, which gives you the advantage of enhancing your security.

 5 shows a state diagram in which a security film to which the diffractive lens array unit of the present invention is applied is applied. As shown in FIG. 5, the security film 1 manufactured by forming the diffraction lens array unit 3 by two-dimensionally arranging the diffraction lens 2 in the form of a specific image or the like, may be a security document 10 such as a card or a banknote. By attaching, aesthetics and security can be increased.

The observer can confirm the image, pattern, text, etc. enlarged, reduced or dynamically changed by the security film (1) to which the diffractive lens array unit is applied (8) and the effect of changing the image and color by diffracted light (10). ) Can easily determine the authenticity.

FIG. 6 shows a state diagram in which the security film to which the diffractive lens array unit of the present invention is applied is applied to the security document 10 having the image unit 5 separately formed. The diffraction lens array portion is applied to the security film 1 is applied to the transparent substrate to the diffraction lens array portion 3 by the embossing method (the diffractive lens array portion may be manufactured separately from the transparent substrate portion and bonded to constitute the present invention The purpose and effect to be obtained are the same.) The transparent functional part 6 is formed on the lower side.

That is, in the embodiment shown in FIGS. 3 and 4, the image unit 5 is removed, and the image unit 5 is a method of separately applying the printing to the security document 10. The security film 1 to which the diffractive lens array is applied is superimposed on the image part 5 of the pattern which cannot be seen with the naked eye, which is printed in advance on the security document 10, so that the implemented image 8 can be observed. The authenticity of the document 10 can be determined.

It is apparent to those skilled in the art that the present invention is not limited to the embodiments described and that various modifications and variations can be made without departing from the spirit and scope of the invention. Accordingly, all such modifications or variations will be belong to the claims of the present invention.

If you make a security sheet with a diffractive lens array unit separately and check the image pattern applied to the security document in advance, it can be used as an identifier to identify the authenticity of the security document.

By applying the security film to which the diffraction lens array unit of the present invention is applied to various security documents such as banknotes, securities, passports, national ID cards, etc., it can provide a very useful effect in the industry, such as greatly contribute to the prevention of forgery and crime prevention throughout the industry. have.

1A is a cross-sectional view showing a cross-sectional shape of a general refractive lens;

1b to 1e are cross-sectional views showing the shapes of various diffractive lenses 1e,

2a to 2b are plan views of two-dimensional array of diffractive lenses,

3 is a cross-sectional view of a security film to which the diffractive lens array unit is applied according to an embodiment of the present invention;

4 is a cross-sectional view of a security film to which the diffractive lens array unit according to another embodiment of the present invention;

5 is a state in which the security film to which the diffractive lens array unit of the present invention is applied;

6 is a state diagram in which the security film to which the diffractive lens array unit of the present invention is applied to a security document in which an image unit is separately formed.

<Description of Symbols for Main Parts of Drawings>

1: Security film with diffractive lens array

2: diffraction lens 3: diffraction lens array portion

4: transparency base material 5: image part

6: transparency function part 7: adhesive part

8: Implemented Image 9: Color Change by Diffracted Light

10: security document

Claims (11)

A plurality of diffractive lenses for diffracting incident light; A transparent base portion on which a diffractive lens array portion formed with the diffractive lenses are arranged; An image unit positioned below the transparent substrate and having various patterns or images formed thereon; And a transparency function unit formed at the lower side of the image unit and having a visual additional function applied thereto. A plurality of diffractive lenses for diffracting incident light; A diffractive lens array unit in which the diffractive lenses are arranged; A transparent base portion to which the diffractive lens array portion is attached; An image unit in which various patterns or images are formed; And a transparency function unit formed at the lower side of the image unit and having a visual additional function applied thereto. A plurality of diffractive lenses for diffracting incident light; A transparent base portion on which a diffractive lens array portion formed with the diffractive lenses are arranged; And a transparency function unit formed under the transparency base unit and having a visual additional function applied thereto. A plurality of diffractive lenses for diffracting incident light; A diffractive lens array unit in which the diffractive lenses are arranged; A transparent base portion to which the diffractive lens array portion is attached; And a transparency function unit formed under the transparency base unit and having a visual additional function applied thereto. The method according to any one of claims 1 to 4, The diffractive lens has a circular edge and a plurality of edges are formed on the surface in a concentric shape with the edge, The edge shape is a security film to which the diffractive lens array unit is characterized in that the configuration consisting of a shape selected from a sawtooth, multiple steps, steps, triangles. The method according to any one of claims 1 to 4, The diffractive lenses of the diffractive lens array unit are arranged two-dimensionally and the security film is applied to the diffractive lens array unit, characterized in that configured to observe the phenomenon of the image and color change by the diffraction in the image front direction. The method according to claim 1 or 2, The image unit security film is applied to the diffractive lens array unit, characterized in that the image is configured to look separated in the focal length position of the diffraction lens. The method according to claim 1 or 2, The image unit is a security film to which the diffractive lens array unit is characterized in that multiple images are printed. The method according to any one of claims 1 to 4, The transparent film is a security film is applied to the diffractive lens array portion, characterized in that formed by forming a semi-transparent thin film on a material having a high refractive index. The method according to claim 1 or 2, And the adhesive part is configured by adding an additional security element. A security document, characterized in that the security film produced by the method according to any one of claims 1 to 10 attached to the document not only to make the image appear dynamically, but also to show the color change by diffraction.

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