RU2403601C2 - Method of making optical two-way reflecting protective apparatus and protective apparatus made using said method - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: method involves making protective element consisting of several layers and has a reflecting layer which enables change of colour in a defined range of the spectrum of reflected light depending on its angle of incidence or viewing angle, and on the other side the protective element also consists of several layers and has polarised latent image which can be viewed using polarisation filters.

EFFECT: more reliable protection from forgery and authentication of protected objects.

37 cl

Description

The invention relates to the field of protection against falsification and authentication of valuable documents, in particular, to the manufacture and production of optical security elements that carry a combination of various security features intended for both quick operational verification of the authenticity of the protected object and for detailed instrumental authentication.

Currently, for protection against counterfeiting and as authenticity marks of protected objects, combinations of various printing protection means are used, in particular watermarks, microtext, special inks, latent images based on colorless embossing and kipp effect, etc., as well as using magnetic , holographic, optical and other methods. Among the protective elements with variable optical properties, the most difficult to reproduce are elements containing latent images visible only in polarized light. The so-called color-changing canvases were widely used in the manufacture of protective equipment: the color of the light ray reflected from such a cloth depends on the viewing angle or the angle of incidence of light. Angular dependences of the frequency of reflected light are set during the manufacturing process and are individual machine-readable features. Color-changing films and coatings are diverse in nature - liquid crystal, pigment, diffraction, interference - cluster and multilayer-film, etc. Here, mainly interference films are considered.

The material for protecting banknotes and the method of its manufacture are described in US 4705300, while a layer carrying a dye for shifting the frequency range and forming a color-variable image is used as part of the multilayer element. US Pat. No. 7,081,282 describes a method for color-variable marking with pigments and forming a color-variable image with metal.

The disadvantages of the above methods is the uniformity of the generated color-variable image and use as a working only one side of the protective element.

Recently, mainly in protective elements, combinations of several security features have been used, including a color-changing effect. For example, in RU 2005106243 A and RU 200613334 A, for the protection of banknotes, documents, packaging, and the manufacture of various labels, a combination of a color-changing effect is used with a wide range of security features, such as piezoelectric properties, electrical conductivity and / or magnetic properties and / or fluorescence, any visible information, various types of pigmentation, isotopic methods and DNA analysis.

As can be seen from the consideration of the presented examples, with a huge number of combinations of the color-changing effect with other protective features, in all cases the protective element has only one working side that carries a certain group of protective features.

A similar situation is observed in the field of latent polarized image: a combination of any visible information with a latent polarized image is described in US 6124970, in application EA 200801396 dated August 11, 2008. In the publication WO 01/00418 A1 for the protection of banknotes, documents, plastic cards, diffraction is proposed structure in reflective and transparent versions, into which one can introduce a certain non-specific polarization structure obtained by the photophysical method.

In all the cases cited, only one front side is working, there is no combination of a latent polarized image with a color-changing effect, and the color-changing image is either absent or monotonous.

Closest to the claimed method is a method of manufacturing a security element that carries two security features: a latent polarized image obtained by direct metal printing on the surface of a transparent optically anisotropic substrate, and any visible information (application EA 200801396 dated August 11, 2008).

The disadvantages of the method according to EA 200801396 are the use of only one working side for the formation of security features and the absence of a combination of a hidden polarized image with a color-changing effect.

The objective of the present invention is to remedy these shortcomings, as well as to increase the level of protection and increase the reliability and stability of protective elements against counterfeiting, copying and imitation by creating a protective optical device having two working sides, each of which has its own security features with a high degree of protection from copying and counterfeiting by direct printing, moreover, both groups of security features are based on common structural components in the scope of the protective equipment; when using a double-sided security element as a plastic banknote or plastic card or as a document page, all security features on both sides of the element are available for prompt and detailed instrumental authentication of the protected object without violating the integrity of the object.

In the case of using a double-sided security element in the form of labels or tags that are attached to the protected object with some kind of glue, only one side - one group of security features - is available for operational verification, while security features located on the opposite side of the item are hidden and are used only for detailed instrumental testing or destructive analysis.

A two-sided protective element is an integral indivisible product: when you try to mechanically separate the element into its components, some protective signs disappear, because part of the structural components of the protective agent is common to two groups of features. The use of a double-sided protective agent significantly increases the reliability of protection against counterfeiting and authentication of protected objects. As the main security features, a latent polarized image on one side of the security element and a color-changing image on its opposite side are selected, in addition, each side of the element carries additional security features. Moreover, the protective element is made in such a way that it has high mechanical, chemical, radiation stability and stability in a wide temperature range of all the protective features included in the element.

In this invention, this problem is solved by creating a method for manufacturing a protective agent, as well as means of increased reliability obtained in this way.

According to a first aspect of the invention, there is provided a method for manufacturing an optical double-sided reflective protective device, consisting of the first and second protective elements, comprising

- provide a transparent carrier, made with essentially uniform throughout the volume of optical anisotropy having two working sides, which are used to form an independent first and second protective elements, while

- to form an independent first protective element, at least a reflective layer is deposited on at least one portion of the carrier on which a absorbing layer having a selective absorption in the specially selected regions of the optical spectrum of the visible range is applied, on which a coating is applied that provides a color change of the reflected beam depending from the angle of incidence of light or viewing angle, which is uniformly coated with a thin transparent protective first outer layer, and

- to form an independent second protective element by direct printing, a reflective latent polarized image is formed at least on a portion of the other side of the medium, a thin transparent protective second outer layer is uniformly applied over the entire surface of the polarized image.

In this case, a carrier of a transparent depolarizing material is preferably used, preferably in the form of a phase plate.

Preferably, the material of the reflective layer is selected from the range: aluminum, copper, chromium, iron, titanium, silver, gold, as well as alloys and ligatures of these metals. In this case, the reflective layer is applied by vacuum deposition. It is possible to apply a reflective layer by chemical deposition.

It is also possible to use a reflective diffraction grating or a reflective hologram as a reflective layer.

It is preferable to use an absorbing layer, which is a single-color discrete image from a number: ornaments, letters, numbers, bar codes. It is possible to perform an absorbing layer in the form of a multi-color discrete image selected from a number of: ornaments, letters, numbers, numbers, logos.

In this case, the absorbing layer is applied by direct printing, selected from a number of: flexography, gravure printing, screen printing.

Preferably, as a coating, providing a color change of the reflected beam depending on the angle of incidence or viewing angle, to use a varnish coating containing a color-changing pigment. It is desirable to use a multilayer interference coating.

It is desirable to provide a color change of the reflected beam depending on the angle of incidence or viewing angle to form a coating by sequentially applying to the surface of the absorbing layer at least one optically transparent isotropic dielectric separation layer with a refractive index of not higher than 1.65 and at least one transparent for visible light metal layer.

A metal layer transparent to visible light is selected from the series: aluminum, copper, chromium, iron, titanium, silver, gold, as well as alloys and ligatures of these metals, dielectrics, semiconductors, 2-10 nm thick.

Preferably, the dielectric separation layer is made of magnesium fluoride. The dielectric separation layer is applied by vacuum spraying. It is also possible to apply a separation layer by any printing method.

A metal layer transparent to visible light is deposited by chemical deposition. It is also possible to apply a metal layer transparent to visible light by vacuum deposition.

According to the invention, lacquer layers are used as the transparent protective layers of the first and second outer layers.

It is advisable to include in the transparent protective first and second outer layers pigments distributed in their volume that are transparent to visible light.

It is preferable to use pigments with color-changing properties.

It is possible to include luminescent labels in the transparent protective first and second outer layers.

It is preferable to perform transparent protective first and second outer layers as carriers of an image rendered in a narrow frequency range in the visible part of the optical spectrum.

It is possible to carry out transparent protective first and second outer layers as carriers of laser marking marks.

It is possible to use a transparent hologram as a transparent protective layer of the first and second outer layers.

Preferably, a multicolor visible image is additionally applied to the surface of the transparent protective outer layer of the at least one protective element.

It is advisable to perform a hidden polarized image by dashed lines.

It is also possible to carry out a hidden polarized image in halftone rasterized.

According to the invention, the latent polarized image is preferably formed from a metal selected from the series: aluminum, copper, chromium, iron, titanium, silver, gold, as well as alloys and ligatures of these metals.

Preferably, the latent polarized image is formed in the form of a reflective diffraction grating or a reflective hologram.

Preferably, latent polarized images are formed using the direct printing method, which is thermal transfer printing or hot stamping.

It is possible to form a latent polarized image by direct printing, which is a vacuum deposition.

Preferably, the first and second security elements are formed to withstand temperatures of 180 ° C.

It is preferable to form one of the security elements so that it forms part of at least one of: a self-adhesive label, packaging, banknote, passport, plastic card and other valuable documents.

According to a second aspect of the invention, there is provided an optical double-sided reflective protective device containing a flat optically anisotropic transparent carrier, each side of which carries its own protective element, while one protective element contains a reflective layer that provides a color change in a certain range of the reflected light spectrum depending on its angle a fall or viewing angle, and several additional security features, and the other security element contains a hidden polarized image visualized using polarization filters and several additional security features, wherein the protective means are formed of said layers according to the above method.

The invention is further illustrated by the example of its implementation using the drawings.

Figure 1 is a side view of a protective agent according to one embodiment of the invention.

Figure 2 is a side view of a protective device according to another embodiment of the invention.

Figure 3 is a view of the left side of the protective means according to any variant implementation of the invention.

4 is a view of the right side of the protective means according to any variant implementation of the invention.

To implement the method of manufacturing an optical double-sided reflective protective means shown in figure 1, perform the following.

A transparent carrier 1 is prepared, made with optical anisotropy substantially uniform throughout the volume, both sides of which will be working and, accordingly, used to form the first “A” and second “B” security elements. The carrier 1 may be made of a transparent depolarizing material. You can use 1 phase plate as a carrier.

The first protective element A is formed on one side of the carrier 1. For this, at least a portion of the side of the carrier 1 is coated with a reflective layer 2 by vacuum deposition, either by hot stamping, or by chemical deposition, or by attaching some kind of adhesive to the carrier 1. The reflection layer can be made of metal, or a diffraction grating or a reflection hologram can be used as the reflection layer. The metal for the reflective layer 2 is selected from the series: aluminum, copper, chromium, iron, titanium, silver, gold, as well as alloys and ligatures of these metals.

Next, on the reflective layer 2 by any printing method, for example, by direct printing, selected from the series: flexography, intaglio printing, screen printing, an absorbing layer 3 is applied, having selective absorption in specially selected regions of the optical spectrum of the visible range. The absorbing layer 3 can be monochromatic - continuous or discrete, or multicolor in the form of patterns, signs, etc.

On top of the absorbing layer 3, a color-changing coating 4 is applied, configured to provide a color change of the reflected beam depending on the angle of incidence of the light or viewing angle. Coating 4 may be a composition comprising a color-changing pigment, for example from the Colorstream family of Merck KGaA, Darmstadt, Germany, applied by any printing method. As coating 4, for example, a varnish containing a color-changing pigment is used.

In another embodiment of the invention, coating 4 may be multilayer interference. Figure 2 shows a side view of a protective agent containing a coating 4, consisting of at least two layers. The first layer 8 is made of at least one optically isotropic transparent dielectric separation layer 8 with a refractive index not higher than 1.65, and the second layer is made of at least one metal layer 9 transparent to visible light. The dielectric layer 8 can be applied by vacuum deposition of magnesium fluoride. For the metal layer 9, you can use aluminum, copper, chromium, iron, titanium, silver, gold, as well as alloys and ligatures of these metals, dielectrics, semiconductors, 2-10 nm thick, deposited by vacuum deposition or chemical deposition.

In conclusion, all this is uniformly coated with a thin transparent protective first outer layer 5 having high mechanical strength and abrasion resistance. Moreover, according to the invention, the protective layer may include any pigment that transmits visible light. It is possible to use pigments with color-changing properties.

Thus, the first security element A includes a carrier 1, a reflective layer 2, an absorbent layer 3, a coating 4 and an outer layer 5.

The second protective element B is formed on the other side of the carrier 1. For this, at least on a portion of this side of the carrier 1, a reflective latent polarized image 6 is formed by direct printing. Image 6 may be dashed, grayscale rasterized, in the form of a reflective diffraction grating or a reflective hologram. Image 6 is formed from a metal selected from the series: aluminum, copper, chromium, iron, titanium, silver, gold, as well as alloys and ligatures of these metals, by direct printing in the form of thermal transfer metal foil, or hot stamping metal foil, or vacuum sprayed metal.

Further, the surface of this side of the carrier 1, at least in the region of the portion of the polarized image 6, is uniformly coated with a thin transparent protective second outer layer 7, for example, a varnish layer or a transparent polymer layer containing a holographic image. In this case, the protective layer of varnish can contain any pigment transparent to visible light, including color-changing. In addition, the outer layer is a carrier of additional protective features, such as fluorescent in the ultraviolet and infrared regions, signs recorded in a narrow spectral region of the visible range, laser marking, etc. The surface of the transparent protective layer can be a carrier of a transparent visible multicolor image or a relief colorless ornament . Application as a protective layer of a polymer film containing a transparent holographic image, increases the reflectivity of the protective layer and, among other things, increases the external attractiveness and protective properties of the element.

In this way, a second security element B is obtained which includes a carrier 1, a reflection layer 2, a latent polarized image 6, and an outer layer 7.

The outer layers 5 and 7 used to protect the first and second elements A and B may contain luminescent labels, or images visualized in a narrow frequency range in the visible part of the optical spectrum, or laser marking signs or can be made in the form of a transparent hologram. In this case, it is possible to apply a multicolor visible image to the surface of the transparent protective outer layer of at least one of the outer layers.

According to the invention, the security elements A and B are formed in the form of at least a part of the object of protection, for example, a banknote, a self-adhesive label, a plastic card, a package or some kind of document.

The methods and materials used provide protective elements A and B that can withstand temperatures of 180 ° C.

The latent polarized image is visualized using a circular polarizer or a linear polarizer, and when visualizing the latent image in circularly polarized light, the sealed areas appear dark blue and whitespace as a light background, and when visualizing the latent image in linearly polarized light, the sealed areas appear bright , and whitespace like a dark background.

According to a second aspect of the invention, according to the steps of the above-described method, in accordance with the first aspect of the invention, an optical double-sided reflective protective means shown in the accompanying drawings is obtained, which comprises two protective elements A and B. The first protective element A includes a carrier 1 coated with at least one portion of this side with a reflective layer 2 and a color-changing coating 4. The second protective element B includes an optically anisotropic carrier 1 with a hidden polarization formed on it image 6 applied to at least one portion of the carrier 1 by direct printing.

As a result, as shown in FIG. 3, images with different color-changing characteristics are obtained on one side of the medium, which are checked visually; and on the opposite side - a practically invisible image for the naked eye and a clear contrast image when viewed in polarized light, as shown in Fig.4.

Polymer films obtained by the extrusion method and having high transparency are selected as the optically anisotropic carrier. The total amount of optical loss during the passage of light through the carrier should not exceed 10%. These conditions are met by materials such as thin layers of polypropylene, polyethylene terephthalate, polyvinylidene fluoride, polytrifluorochlorethylene, polycarbonate and some other polymers. To reduce optical loss, the thickness of the carrier is selected as low as possible for each specific protected object, usually 12-36 microns. In this case, metal is used as a reflective layer, a reflective hologram or a holographic hot stamping foil can be used, as well as a reflective diffraction grating. The layer that selectively absorbs light in the visible range is applied by any printing method and can be solid monochrome, which leads to a change in the saturation and spectral shift of the color of the coating compared to an unpainted reflector; may be a single-color image against the background of an unpainted reflector, the image in this case is a uniform color variable; or it can be multicolor, in this case each element of a color-changing image will have its own color-changing picture, different from other elements. To ensure color variation in the interference version, a metal layer is required, which is almost transparent to visible light and acts as an optical resonator deposited on top of the dielectric separation. A metal layer 2-10 nm thick is applied by vacuum deposition or chemical deposition. A dielectric layer, inorganic or polymeric, with a thickness of 0.2-1.5 microns is applied by vacuum spraying or by any printing method on top of a layer that selectively absorbs visible light. The outer protective layer performs mainly the function of mechanical protection, is applied either in the form of varnish by printing, or in the form of a thin polymer film, attached using any glue. Moreover, according to the invention, the protective layer may include any pigment that transmits visible light. In addition, the outer layer is a carrier of additional protective features, such as fluorescent in the ultraviolet and infrared regions, signs recorded in a narrow spectral region of the visible range, laser marking, etc.

An optically anisotropic medium is an integral functional component of a latent polarized image. The nature of optical anisotropy is determined by the spatial microstructure of the polymer material, for example, biaxially oriented polyethylene terephthalate depolarizes circular light, and uniaxially oriented polypropylene is a phase plate. So, the use of a phase plate as a carrier, for example, a quarter-wave one, leads to the appearance of a bright colored background when visualizing a latent image in both linear and circular polarized light, the type of image being visualized depends on the angle of rotation of the polarizer.

The claimed invention can be used to protect against falsification of valuable documents: passports, vouchers, banknotes, stocks, checkbooks and to identify the authenticity of these documents, as well as for the manufacture of secure plastic banknotes, plastic cards and documents.

Claims (37)

1. A method of manufacturing an optical double-sided reflective protective means, consisting of the first and second protective elements, which perform the following:
a) provide a transparent carrier, made with essentially uniform optical anisotropy throughout the volume, having two working sides, which are used to form an independent first and second protective elements, while
b) in order to form an independent first protective element, at least a reflective layer is deposited on one side of the carrier on one side of the carrier, onto which an absorbing layer is applied having a selective absorption in selected regions of the optical spectrum of the visible range, onto which a color changing coating is applied, which provides a color change of the reflected beam depending on the angle of incidence of light or viewing angle, which is uniformly coated with a thin transparent protective first outer layer containing additional itnye signs and
c) for the formation of an independent second protective element by direct printing, a reflective latent polarized image is formed at least on a portion of the other side of the medium, a thin transparent transparent second protective layer containing additional security features is uniformly applied over its entire surface. 2. The method according to claim 1, in which the carrier is made of a transparent depolarizing material. 3. The method according to claim 1, wherein a phase plate is used as the carrier. 4. The method according to claim 1, in which the material of the reflective layer is selected from the series: aluminum, copper, chromium, iron, titanium, silver, gold, as well as alloys and ligatures of these metals. 5. The method according to claim 1, in which the reflective layer is applied by vacuum spraying. 6. The method according to claim 1, in which the reflective layer is applied by chemical deposition. 7. The method according to claim 1, in which a reflective diffraction grating is used as a reflective layer. 8. The method according to claim 1, in which a reflective hologram is used as a reflective layer. 9. The method according to claim 1, in which the absorbing layer is a single-color discrete image from a number of: ornaments, letters, numbers, bar codes. 10. The method according to claim 1, in which the absorbing layer is a multi-color discrete image from a number of: ornaments, letters, numbers, numbers, logos. 11. The method according to claim 1, in which the absorbing layer is applied by direct printing, selected from the series: flexography, gravure printing, screen printing. 12. The method according to claim 1, in which the coating, providing a color change of the reflected beam depending on the angle of incidence or viewing angle, is a varnish coating containing a color-changing pigment. 13. The method according to claim 1, in which the coating, providing a color change of the reflected beam depending on the angle of incidence or viewing angle, is a multilayer interference coating. 14. The method according to item 13, in which the coating, providing a color change of the reflected beam depending on the angle of incidence or viewing angle, is formed by sequentially applying to the surface of the absorbing layer at least one optically isotropic dielectric separation layer transparent to visible light with a coefficient refraction not higher than 1.65 and at least one metal layer transparent to visible light. 15. The method according to item 13, in which the dielectric separation layer is made of magnesium fluoride. 16. The method according to item 13, in which the dielectric separation layer is applied by vacuum spraying. 17. The method according to item 13, in which the metal layer transparent to visible light is selected from the series: aluminum, copper, chromium, iron, titanium, silver, gold, as well as alloys and ligatures of these metals, dielectrics, semiconductors, thickness 2 -10 nm. 18. The method according to item 13, in which the metal layer, transparent to visible light, is applied by vacuum spraying. 19. The method according to item 13, in which a metal layer transparent to visible light is deposited by chemical deposition. 20. The method according to claim 1, in which as a transparent protective first and second outer layers using layers of varnish. 21. The method according to claim 1, in which the transparent protective first and second outer layers contain pigments distributed in their volume, transparent to visible light. 22. The method according to item 21, in which use pigments with color-changing properties. 23. The method according to claim 1, in which the transparent protective first and second outer layers contain luminescent labels. 24. The method according to claim 1, in which the transparent protective first and second outer layers are an image carrier rendered in a narrow frequency range in the visible part of the optical spectrum. 25. The method according to claim 1, in which the transparent protective first and second outer layers are a carrier of laser marking marks. 26. The method according to claim 1, in which a transparent hologram is used as the protective first and second outer layers. 27. The method according to claim 1, in which a multicolor visible image is additionally applied to the surface of the transparent protective outer layer of the at least one security element. 28. The method according to claim 1, in which the latent polarized image is dashed. 29. The method according to claim 1, in which the latent polarized image is grayscale rasterized. 30. The method according to claim 1, in which the latent polarized image is formed from a metal selected from the series: aluminum, copper, chromium, iron, titanium, silver, gold, as well as alloys and ligatures of these metals. 31. The method according to claim 1, in which the latent polarized image is formed in the form of a reflective diffraction grating. 32. The method according to claim 1, in which a latent polarized image is formed in the form of a reflective hologram. 33. The method according to claim 1, in which the formation of a latent polarized image is carried out using the direct printing method, which is a thermal transfer printing or hot stamping. 34. The method according to claim 1, in which the latent polarized image is formed by direct printing, which is a vacuum deposition. 35. The method according to claim 1, in which the protective agent is formed in such a way that all the protective elements withstand temperatures of 180 ° C. 36. The method according to claim 1, in which the protective agent is formed in such a way that it forms part of at least one of: a self-adhesive label, packaging, banknote, passport, plastic card and other valuable documents. 37. An optical double-sided reflective protective device containing a flat optically anisotropic transparent carrier, each side of which carries its own protective element, while one protective element contains a reflective layer having selective absorption in selected regions of the optical spectrum of the visible range, an absorbing layer on which color changing is applied a coating providing a color change of the reflected beam depending on the angle of incidence of the light or viewing angle, covered with a thin transparent protection the first outer layer containing additional protective features, and the other protective element contains a hidden polarized image visualized using polarizing filters, on the entire surface of which a thin transparent protective second outer layer containing additional protective features is uniformly applied, the protective means being made in accordance with by the method described in claims 1-36.

Images