EA017762B1 - Protection element for protecting valuable documents against forgery and duplication, method for making said protection element and method for verifying an object to be protected containing said protection element - Google Patents

Abstract

The invention relates to a protection of objects to be protected, e.g. to protection of valuable documents against forgery and duplication using a protection element which comprises a transparent substrate 1, on the working surface of which is formed at least one opaque metal element 3 of holographic image and at least one portion having a predetermined optical transmission within a 10 to about 90% range and formed by metal microraster elements 2 of 5-500 mkm size of the preset form and frequency, carrying a pre-programmed information, wherein said at least one element and at least one portion are in spatial-specified accordance to each other, forming a combined image of the preset structure, form and content; an optically variable transparent layer 4 changing its color in a reflected and passing light depending on light angle, the layer 4 is applied on the whole working surface of said substrate over at least one element and at least one portion; a transparent protection layer 5 applied over the optically variable transparent layer 4. A method is also described of making said protection layer and a method of verification thereof.

Description

The invention relates to the field of protection of objects to be protected, in particular for protecting valuable documents from counterfeiting and copying and identifying their authenticity, in particular a security element for protecting valuable documents, to a method for manufacturing a security element and a method for verifying said security element.

State of the art

An object of the present invention is to provide a combined holographic and micro-raster protective optical means, i.e. a security element with several degrees of protection against counterfeiting, which is at the same time evidence of the authenticity of the protected object. Moreover, the claimed security element, which is a transparent polymer film, can carry several different additional security features, which significantly increases the level of protection. The tool is intended to protect against counterfeiting and as a sign of authenticity of banknotes, passports and other valuable documents, plastic cards, and strict reporting forms. The main way to use a protective optical device (element) in the form of a ribbon, strip or translucent / reflective window in the protected object, or a sign applied to the protected object by hot stamping, or in the form of a self-adhesive label or tag. It is also possible to use a protective agent in the form of a cloth of a plastic banknote, a plastic page of a document, in the form of a layer covering the paper page of a document, a plastic card.

Currently, for protection against counterfeiting and as authenticity signs of protected objects, special means of protection and authentication signs are used (in addition to various printing protection means) built into the protected product in the form of a polymer transparent or translucent window that carries one or more security features, such as various visible images, a color change effect in transmitted and reflected light, diffraction, holographic and other optical effects. Among the protective elements with variable optical properties, the most difficult to reproduce are elements containing several protective features of various physical nature.

The concept of using several security features of various nature was used in I8 patent 7875338, cl. IPC Β42Ό 15/00 dated 11/07/2002, in which a two-sided plastic element with a diffraction grating covered with a metal layer on the first side and a metal layer with selective demetallization and a color-changing layer on the other working side is disclosed. However, the described tool is completely opaque, which does not allow using the capabilities of light-transmitting windows and complicates the verification process.

The security (identification) element disclosed in I8 patent 7463154, class. IPC Β42Ό 15/10 of 03.03.2005, contains a substrate with a layer of metal deposited on it, subjected to selective demetallization to form an antenna for radio frequency identification, while discrete demetallized areas are elements of a complex visible image, and discrete metal sections are elements of a holographic image, however, this element mainly performs not protective, but identification functions and, in addition, has a significant thickness.

Closest to the claimed security element is the security element disclosed in international publication AO 2004098900, class. IPC Β42Ό 15/00 dated 11/18/2004, which is a combination of sections of a metal hologram and sections of various thicknesses formed during selective partial demetallization, while the reflective sections of the element have a color-changing effect. However, demetallized areas do not carry any specific information, therefore, their contribution to the protective functions of the element is low.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a security element used in valuable documents to be protected that has high mechanical strength and carries a set of independent and / or predetermined security features created in demetallization processes in such a way that the reflective sections of the working surface of the security element carry elements holographic image, and light transmitting areas having different optical transmittance / reflection are formed by raster elements of various sizes with different frequencies, carrying visible and hidden information, and are the main protective features, in addition, a color-changing layer formed on a surface consisting of sections with different optical transmittance and reflectivity forms an additional effective protective feature, can be used for protection durable objects.

According to a first aspect of the invention, there is provided a security element for protecting objects to be protected, for example, valuable documents for protection against counterfeiting and copying, the security element comprising a transparent substrate on which at least one opaque metal element of a holographic image and at least one section having a predetermined optical transmission in the range from

- 1 017762 about 10 to about 90% and the formation of metal micro-raster elements of a predetermined shape and frequency, having a size of 5-500 microns, carrying predetermined information, wherein said at least one element and at least one section are in a spatially defined compliance with each other, forming a combined image of a predefined structure, shape and content; a color-changing transparent layer that changes color in reflected and transmitted light depending on the angle of incidence of light, deposited on the entire working surface of the specified substrate on top of at least one element and at least one area; a transparent protective layer deposited on top of a color-changing transparent layer.

At the same time, a transparent polymer film 12-23 microns thick, preferably 15-19 microns thick, selected from the following series is used as a substrate in the protective element: lavsan, polypropylene, polycarbonate, nylon, etc.

In addition, in the protective element, the metal raster elements are configured to use at least one element of various geometric shapes, letters, numbers, text information, ornament or a combination thereof, which are spatially specified according to each other, and, in addition, micro-raster elements include latent images smaller than 50 microns in size, indistinguishable to the naked eye.

According to a first aspect of the invention, a composite image is formed in the security element containing portions of the metal image with an optical transmission of 10-90%.

In addition, the color-changing transparent layer of the protective element changes color depending on the angle of incidence of the light and the optical properties of the light reflecting and transmitting sections of the working surface and is at least a three-layer structure: the upper transparent layer of zinc sulfide is 90-100 nm thick with a refractive index of 2 , 41, the middle layer is a dielectric transparent layer with a thickness of 100-350 nm depending on the desired colors and the amount of color shift from transparent polymer compositions or transparent metal halides allov with a refractive index of 1.3-1.8, the lower transparent layer of zinc sulfide 90-100 nm thick with a refractive index of 2.41.

The transparent protective layer is an abrasion and scratch resistant coating layer or a thin polymer film with a thickness of 12-15 microns, resistant to abrasion and scratches.

According to a first aspect of the invention, the security element is intended to protect, in particular, banknotes, passport pages, plastic cards, vouchers, stocks, check books and is made in the form of a tape or in the form of a self-adhesive label or tag, or in the form of a hot stamping foil.

In addition, the protective element is formed in such a way that withstands temperatures up to 140 ° C.

According to a second aspect of the invention, there is provided a method of manufacturing a security element with forming a combined image formed from the first and second images, wherein the first image is formed by at least one opaque metal element of a holographic image, and the second image is made from a combination of metal micro-raster elements of a predetermined shape and frequency 5-500 microns in size, carrying predefined information, the first and second images being are spatially defined according to each other, and the method comprises the following steps in which:

a) apply a layer of holographic varnish on the working surface of the transparent substrate;

b) apply a metal layer to the surface of the layer of holographic varnish;

c) at least one holographic image element is imprinted in at least one portion of the metal layer forming the first image;

d) in accordance with a predefined pattern, a protective varnish layer is applied to the surface of the metal layer;

e) areas of the metal layer that are not protected by the lacquer layer are subjected to alkaline etching until a predetermined optical transmission is achieved with the simultaneous formation of a plurality of metal micro-raster elements forming the second image, the elements forming the first and second images being in spatially specified correspondence with each other,

f) applying a color-changing transparent layer over the entire working surface of the specified substrate over the elements forming the first and second images, with the formation of a combined image;

g) a transparent protective layer is applied over the color-changing layer, while an alkali-resistant varnish is used as a protective varnish.

In addition, the metal layer that is deposited in step b) is subjected to selective etching with a 1-2% aqueous solution of caustic soda with the addition of 0.1-0.2% sodium glutamate, while the metal sections that are not protected by varnish dissolve.

In addition, the color-changing transparent layer deposited in step e) is configured to change its color depending on the angle of incidence of the light and the optical properties of reflecting and

- 2 017 762 light-emitting portions of the working surface and is a three-layer structure: the upper transparent layer of zinc sulfide 90-100 nm thick with a refractive index of 2.41, the middle layer is a transparent dielectric layer 100-350 nm thick depending on the desired colors and color shift from transparent polymer compositions or transparent metal halides with refractive indices of 1.3-1.8, the lower transparent layer of zinc sulfide 90-100 nm thick, with a refractive index of 2.41.

In this case, the lower and upper layers of zinc sulfide are applied by thermoresistive vacuum deposition, and the middle dielectric layer is applied either by intaglio printing in the case of organic compositions, or by magnetron vacuum deposition of metal halides.

According to a third aspect of the invention, there is provided a method for verifying a valuable object with a security element, in which a combined image formed in the security element is compared with a reference predefined combined image of an exemplary security element and the authenticity of the valuable object is determined based on the comparison.

Moreover, the comparison step comprises a) a visual comparison of the configuration of the combined image with the configuration of the reference predefined combined image.

In addition, the comparison step comprises b) a visual comparison of the optical and color-changing properties of the combined image with the optical and color-changing properties of the reference predefined combined image of the exemplary security element.

Additionally, the comparison step includes c) visualizing the hidden information indistinguishable to the naked eye, the combined image using a microscope and comparing it with the hidden information contained in a genuine exemplary security element.

Description of the figures of the drawings

Signs, elements and advantages of the invention result from the following description of embodiments of the invention with reference to the accompanying figures:

FIG. 1 is a cross-sectional view of a security element;

FIG. 2 is a view of a security element carrying both visible and latent images and the principle of rendering a latent image.

Description of a preferred embodiment of the invention

According to the present invention, the protective element consists of a transparent substrate 1 (Fig. 1), on the working surface of which is applied at least one combined image consisting of the first and second images and forming reflective and light-transmitting portions on the working surface of the protective element. In this case, the first image is formed by at least one element 3 of the holographic image (Fig. 1, 2), which is an opaque holographic image, and the second image is formed by a combination of metal micro-raster elements 2 (Fig. 1, 2), 6 (Fig. 2), where under pos. 2 all micro-raster elements are indicated, and under position 6 - micro-raster elements smaller than 50 microns in visualized form. It should be noted that the reflective sections of the working surface carry elements 3 of a holographic image (the first image), and the light-transmitting sections of the working surface have different optical transmission and are formed by metal micro-raster elements 2 of different sizes with different frequencies, which carry visible and hidden information and form a second image.

A color-changing transparent layer 4 (Fig. 1) is applied to the working surface of the protective element, on top of the first and second images (2, 3). A color-changing transparent layer 4 changes color depending on the angle of incidence of the light and optical properties reflecting and transmitting light of the sections of the working surface and forms a color-changing image in accordance with the configuration of the reflecting and transmitting light sections on the working surface of the protective element; over this color-changing layer 4, a protective layer 5 is applied (Fig. 1), which is resistant to abrasion and scratching.

As the substrate 1, a thin transparent polymer film of a thickness of 12-23 microns, preferably 15-19 microns, made of lavsan, polypropylene, polycarbonate or nylon is used.

Microraster elements 2, 6 (Fig. 1, 2) are made in such a way that in a certain range of sizes of raster elements and their frequencies, optical transmission at a constant frequency increases with increasing sizes of raster elements and decreases with fixed sizes of raster elements with increasing frequency. The sizes of the raster elements vary in the range of 5-500 microns, the optical transmission in the range of 10-90%, the frequency in the range from 2 to 200 raster elements / mm. Raster elements represent various geometric shapes, letters, numbers, text information, ornaments, or combinations thereof. Raster elements in the size range from 5 to 50 μm are indistinguishable to the naked eye, visualized at high magnification (item 6, Fig. 2) and are, therefore, an independent protective feature.

As already mentioned above, the entire working surface of the protective element is covered with a transparent color-changing layer 4, which changes color depending on the angle of incidence of the light and the optical properties of the light reflecting and transmitting portions of the working surface. This color changing layer

- 3 017762 is a three-layer structure:

the upper transparent layer is made of zinc sulfide (Ζηδ) 90-100 nm thick and with a refractive index of 2.41;

the middle layer is a transparent dielectric layer with a thickness of 100-350 nm (depending on the desired colors and the amount of color shift) from transparent polymer compositions or transparent metal halides with refractive indices of 1.3-1.8;

the lower transparent layer is made of zinc sulfide (Ζηδ) 90-100 nm thick and with a refractive index of 2.41.

The transparent protective layer 5 is resistant to abrasion and scratching and is a thin lacquer layer with a thickness of 0.5 to 1 μm or a thin polymer film 12-15 μm thick made of lavsan, polypropylene or polycarbonate, and completely covers the working surface of the protective element on top of the color-changing layer 4.

Moreover, the security element is formed in such a way that it is a part in the form of a selectively transparent window or strip embedded in one of the protected objects: a banknote, passport page or other similar valuable document, plastic card, voucher, share, checkbook. Also, the protective element can be made in the form of a web, a self-adhesive label or tag and in the form of a hot stamping foil, as well as in the form of cover layers for protecting paper pages of documents and plastic cards by hot lamination.

Thus, the protective element used in the above objects to be protected has high mechanical strength and carries a set of independent and / or predetermined security features created in demetallization processes in such a way that the reflective sections of the working surface of the protective element carry holographic image elements 3, and light transmitting sections having different optical transmittance / reflection are formed by raster elements 2 of various sizes with different frequency, which carry visible and hidden information and are the main protective features, in addition, the color-changing layer 4, formed on the surface, consisting of areas with different optical transmittance and reflectivity, forms an additional effective protective feature, can be used to protect long-term objects.

In addition, the security element according to the first aspect of the invention is designed to withstand temperatures up to 140 ° C.

The combined color variable image formed in the security element on the working surface of the element is one of the graphic signs: letter, number, letter or number sequences, ornaments, logos, bar codes, and other encoded information.

A method of manufacturing a security element comprises the following steps:

a) provide a transparent substrate 1 of a polymer film;

b) on the entire working surface of the transparent substrate 1, a layer of holographic varnish is applied in a flexographic manner;

c) a metal layer is applied to the working surface of the protective element over a layer of holographic varnish;

d) at least one portion of the working surface covered with a metal layer is imprinted with at least one element 3 of the holographic image with the provision of the first image;

e) selectively, in accordance with a predetermined pattern, a thin lacquer layer resistant to an alkaline medium is applied to at least one portion of the working surface covering at least a portion of the metal holographic image;

f) areas of the metal layer that are not protected by the lacquer layer are subjected to alkaline etching until a predetermined optical transmission is achieved, with the simultaneous formation of a plurality of metal micro-raster elements 2 forming a second image, the first and second images being in spatially specified correspondence with each other;

g) after washing and drying, a transparent color-changing layer 4 is applied to the surface of the resulting combined image, changing color depending on the angle of incidence of the light and on the optical properties of the light reflecting and transmitting sections of the working surface;

h) a transparent protective layer 5 is applied over the color-changing transparent layer 4 by intaglio printing in the form of a thin lacquer coating or a transparent polymer layer is attached using hot or cold lamination.

The metal layer for forming the metal (reflective) hologram is applied by the method of vacuum thermoresistive spraying.

For the formation of a color-variable layer 4, the upper and lower transparent layers Ζηδ with a thickness of 90-100 nm with a refractive index of 2.41 are applied by vacuum thermoresistive spraying, and the average dielectric transparent layer with a thickness of 100-350 nm (depending on the desired colors and color shift) consists of transparent polymer compositions or transparent metal halides with refractive indices of 1.3-1.8, while the transparent layers of metal halides

- 4 017762 applied by vacuum magnetron sputtering, and the transparent polymer layers by intaglio printing.

A method of verifying a valuable object with a security element is to compare the combined image formed in the security element with a reference predefined combined image of an exemplary security element, and on the basis of this comparison, the authenticity of the valuable object is revealed.

In this case, the comparison step includes a visual comparison of the configuration of the combined image with the configuration of the reference predefined combined image.

In addition, the comparison step comprises a visual comparison of the optical and color-changing properties of the combined image with the optical and color-changing properties of the reference predefined combined image of the exemplary security element.

The verification of the authenticity of hidden protective elements is carried out when visualizing hidden information indistinguishable to the naked eye, a combined image using a microscope and comparing it with hidden information contained in a genuine exemplary protective element, and hidden micro-raster elements 2 can be seen using a microscope or similar means by at least fifty times magnification, as illustrated clearly in FIG. 2 under pos. 6.

The claimed invention can be used to protect valuable documents from forgery and copying and identification of their authenticity.

Claims (21)

CLAIM 1. A security element for protecting valuable documents from counterfeiting and copying, comprising a transparent substrate, on the working surface of which is formed at least one opaque metal element of a holographic image and at least one portion having a predetermined optical transmission in the range from about 10 to about 90% and formed by metal micro-raster elements of a predetermined shape and frequency, having a size of 5-500 microns, carrying predefined information, moreover, the specified at least one element and at least one section are spatially specified with each other, forming a combined image of a predefined structure, shape and content; a color-changing transparent layer that changes color in reflected and transmitted light depending on the angle of incidence of light, deposited on the entire working surface of the specified substrate on top of at least one element and at least one area; a transparent protective layer deposited on top of a color-changing transparent layer. 2. The protective element according to claim 1, in which a transparent polymer film of a thickness of 12-23 microns, preferably 15-19 microns, selected from the following series is used as a substrate: lavsan, polypropylene, polycarbonate, nylon. 3. The security element according to claim 1, in which the metal micro-raster elements are made with the possibility of forming at least one element from various geometric shapes, letters, numbers, text information, ornament, or a combination thereof, in a spatially defined correspondence with each other. 4. The security element according to claim 1, in which the combined image is a different picture of geometric shapes, letters, numbers, text information, ornaments that are spatially specified according to each other. 5. The security element according to claim 1, in which the metal micro-raster elements include latent images less than 50 microns in size, indistinguishable to the naked eye. 6. The protective element according to one of the preceding paragraphs, in which a color-changing transparent layer, which changes color depending on the angle of incidence of the light and the optical properties of reflecting and light-transmitting surfaces, is at least a three-layer structure: the upper transparent layer of zinc sulfide (Ζηδ ) 90-100 nm thick with a refractive index of 2.41, the middle layer is a transparent dielectric layer 100-350 nm thick depending on the desired colors and the amount of color shift from transparent polymer to mpozitsy or transparent metal halides with refractive indices 1.3-1.8; lower transparent layer of zinc sulfide (Ζηδ) 90-100 nm thick with a refractive index of 2.41. 7. The protective element according to one of the preceding paragraphs, in which the transparent protective layer is an abrasion and scratch resistant coating layer. 8. The protective element according to one of the preceding paragraphs, in which the transparent protective layer is a thin polymer film with a thickness of 12-15 microns, resistant to abrasion and scratches. 9. The security element according to one of the preceding paragraphs, which is intended to protect, in particular, banknotes, passport pages, plastic cards, vouchers, stocks, check books and is made in the form of a tape. - 5 017762 10. The security element according to one of the preceding paragraphs, which is formed in the form of a self-adhesive label or tag or in the form of a hot stamping foil. 11. The protective element according to one of the preceding paragraphs, which is formed in such a way that withstands temperatures up to 140 ° C. 12. A method of manufacturing a security element with the formation of a combined image formed from the first and second images, wherein the first image is formed by at least one opaque metal element of a holographic image, and the second image is from a combination of metal micro-raster elements of a predetermined shape and frequency of 5- 500 microns carrying predefined information, the first and second images being spatially specified according to g with a friend, while the method comprises the following steps in which: a) apply a layer of holographic varnish on the working surface of the transparent substrate; b) apply a metal layer to the surface of the layer of holographic varnish; c) at least one holographic image element is imprinted in at least one portion of the metal layer forming the first image; d) in accordance with a predefined pattern, a protective varnish layer is applied to the surface of the metal layer; e) areas of the metal layer that are not protected by the lacquer layer are subjected to alkaline etching until a predetermined optical transmission is achieved with the simultaneous formation of a plurality of metal micro-raster elements forming a second image, the elements forming the first and second images being spatially specified with each other; f) applying a color-changing transparent layer over the entire working surface of the specified substrate over the elements forming the first and second images, with the formation of a combined image; g) a transparent protective layer is applied over the color-changing layer. 13. The method according to item 12, in which as a protective varnish use resistant to an alkaline environment varnish. 14. The method according to item 12, in which the metal layer is subjected to selective etching using a 1-2% aqueous solution of caustic soda with the addition of 0.1-0.2% sodium glutamate, while the metal parts that are not protected by varnish dissolve. 15. The method according to p. 12, in which a color-changing transparent layer, which changes color depending on the angle of incidence of the light and the optical properties of the light reflecting and transmitting surfaces, is a three-layer structure: the upper transparent layer of zinc sulfide is 90,000 nm thick with a refractive index of 2, 41, the middle layer is a dielectric transparent layer with a thickness of 100-350 nm depending on the desired colors and the amount of color shift from transparent polymer compositions or transparent metal halides with refractive indices of 1.3 -1.8, the lower transparent layer of zinc sulfide 90-100 nm thick with a refractive index of 2.41. 16. The method according to clause 15, in which the lower and upper layers of zinc sulfide are applied by thermoresistive vacuum deposition. 17. The method according to clause 15, in which the middle dielectric layer is applied either by intaglio printing in the case of organic compositions, or by magnetron vacuum deposition of metal halides. 18. A method of verifying a valuable object with a security element according to one of claims 1 to 11, in which a combined image formed in the security element is compared with a reference predefined combined image of an exemplary security element, and the authenticity of the valuable object is determined based on this comparison. 19. The method according to p, in which the comparison step contains a visual comparison of the configuration of the combined image with the configuration of the reference predefined combined image of the exemplary security element. 20. The method according to p, in which the comparison step includes a visual comparison of the optical and color-changing properties of the combined image with the optical and color-changing properties of the reference predefined combined image of the exemplary security element. 21. The method according to p, in which the comparison step contains the visualization of hidden information, indistinguishable to the naked eye, the combined image using a microscope and compare it with hidden information contained in a genuine exemplary security element.