EA026699B1 - Optical protection device - Google Patents

Abstract

The invention is related to an optical protection device and a method for manufacture thereof. The optical protection device comprises the following components disposed sequentially: a substrate (1), a separating layer (2), a protective layer (3), a transparent information-carrying layer (4), a light-reflecting information-carrying layer (5) and a jointing layer (6), wherein the transparent information-carrying layer (4) contains at least one holographic image and/or at least one concealed image and/or a colour-variable layer; the light-reflecting information-carrying layer (5) includes at least three light-reflecting sublayers that differ and/or coincide in their colour, dimensions and geometrical shape and are provided on at least a part of the transparent information-carrying layer (4) so as to ensure formation of a multi-colour image. The method for manufacture of the optical protection device includes the steps of provision of a substrate, sequential applying to the substrate the separating layer, the protective layer, the transparent information-carrying layer (4), and the light-reflecting information-carrying layer (5), applying the jointing layer over said light-reflecting sublayers, the area of projection of the protective, jointing and separating layers on the substrate being coincident with the substrate area.

Description

The invention relates to the field of protection of objects to be protected, in particular to the manufacture of optical protective elements that can serve as evidence of the authenticity of the protected objects and can be used to protect against falsification of various valuable items, documents, banknotes, securities, vouchers, stamps of various fees, plastic cards packaging.

State of the art

Currently, various means of printing protection (watermarks, microtext), holographic, photophysical and other methods are used to protect against counterfeiting and as signs (marks) identifying the authenticity of protected objects. Among the protective elements with variable optical properties, the most common and widely used are reflective protective equipment, they can carry both hidden protection signs - polarizing, photoluminescent, and visible, containing diffraction and holographic images. As a rule, diffraction and holographic images have a complex multilevel structure, which is difficult to reproduce and copy, in addition, they are obtained, as a rule, using complex and expensive equipment, so it is difficult to fake them. However, diffraction and holographic images, as a rule, are not protected from imitation, i.e. with the operational control of large arrays of valuable items protected by a complex multi-level hologram, there is a high probability of missing a mark made in the form of a genuine mark, but using a simple rainbow hologram. Here, either instrumental control is required, which significantly reduces the control speed, or it is necessary to introduce clearly visible features that ensure the reliability of visual operational verification. The same applies to reflective protective equipment containing hidden protective features.

The most suitable medium for introducing these features into a multilayer optical protective device is a reflective layer and the space between the reflective layer and the holographic layer. The simplest way to modify a metal reflective layer is to stain it with various dyes. The introduction of visible images between the reflective layer and the information layer is known from the international publication \ UO 91/06925, publ. 05/16/1991 and is a simple, but quite effective way to protect holograms. The formation of a color-changing reflective layer that changes color depending on the angle of incidence of light, are known from patents I8 7224528, publ. 06/16/2005, and I8 7754112, publ. 05/20/2004. However, the proposed methods are more suitable for instrumental rather than operational control, because the bright shine, in the case of a hologram, dampens small details and does not allow you to visually catch non-contrast color transitions of the reflective layer, which significantly reduces the speed of operational control of the authenticity of objects bearing the specified protective mark.

The most interesting is the technical solution disclosed in I8 5815292, publ. 09/29/1998, which consists in creating protective elements with structured discrete reflective layers formed using different metals, in this case a two-color reflective layer is used that carries visible graphic information formed by two layers of metal.

Closest to the claimed invention are the technical solutions disclosed in patent I8 6903850, publ. 06/07/2005. Optical protective means described in this patent document and methods for their preparation generally assume the presence of a continuous polymer carrier and a thin polymer layer into which a holographic image is imprinted, a metal reflective layer is placed between these layers. The formation of a visible metal image is carried out by sequentially spraying three reflective layers with two stages of selective etching after the first and second spraying, and it is possible to obtain a multi-color halftone rasterized metal image as a reflective layer for a holographic image. The holographic labels and tags obtained in this way are an effective protective measure in which the main security feature, the hologram, is reliably protected from imitation and copying.

The serious disadvantages of this technical solution include the use of raster etching, which has many valuable qualities, but significantly reduces the reflectivity of the metal reflector and, therefore, the quality of the hologram.

The objective of the invention is to eliminate the above disadvantages and provide an optical protective device with a high degree of protection against unauthorized use, provided by the introduction of a transparent information-bearing layer with holographic and / or latent images and / or a visible color-variable layer and the formation of a reflective information-bearing layer containing at least three, differing and / or coinciding in color, size and geometric shape, reflective sublayer.

Moreover, the achievement of the technical result is ensured by the creation of a protective holographic means with a visible reflective color-changing image that does not violate the high reflectivity of the reflective layer having a high degree of protection against repeated

- 1,026,699 use, copying and imitation.

SUMMARY OF THE INVENTION

According to a first aspect of the invention, an optical protective device is claimed comprising a sequentially arranged substrate (1), a separation layer (2), a protective layer (3), a transparent information carrier layer (4), a reflective information carrier layer (5), and a connecting layer ( 6), while the transparent information-bearing layer (4) contains at least one holographic image, and / or at least one latent image, and / or a color-changing layer; the reflective information-bearing layer (5) contains at least three different and / or matching in color, size and geometric shape, reflective sublayers provided for at least a part of the transparent information-bearing layer (4) in such a way as to ensure the formation of a combined color image.

Moreover, the substrate (1), which is the carrier of the protective device, is made of a transparent polymer material or composite material containing a transparent polymer material with a thickness of 12-50 microns; the separation layer is made of synthetic wax compositions and has a thickness of 0.2-0.5 microns; the protective layer is made of one row material: polyvinylidene fluoride, polytrifluorochlorethylene, polycarbonate with a thickness of 1-2 microns.

When the thicknesses of the layers are below the values of the specified limits for the respective materials, the strength and mechanical characteristics of the protective device are not achieved, the protective device is deformed and / or destroyed when used. The implementation of layer thicknesses above the values of the specified limits for the respective materials is impractical due to the achievement of sufficient strength at these values.

In addition, the transparent information-bearing layer (4) is made of a transparent polymer material with a thickness of 0.8-1.0 μm, and at least one holographic image is imprinted on the entire surface or at least on its part, and / or at least one latent image by intaglio printing using photoluminescent dyes, and / or a color-changing layer is applied by flexographic printing and vacuum spraying.

In this case, a color-changing layer deposited on a transparent information-bearing layer (4) consists of two layers of zinc sulfide and / or titanium dioxide and / or bismuth oxide and / or silver and a dielectric separation layer between them, while two layers, for example, zinc sulfide, coincides with the area of the transparent information carrier layer (4), and the area and shape of the dielectric separation layer is made with the possibility of coincidence or mismatch with the area of the transparent information carrier layer (4).

At the same time, in the optical protective device, the first reflective sublayer carrying visible information is made of aluminum with a thickness providing an optical density of 1.9-2.1; a second reflective sublayer carrying visible information is made of copper with a thickness providing an optical density of 0.9-1.1; the third reflective sublayer is made of one material of the following series: zinc sulfide, titanium oxide, gold, silver, bismuth oxide with a thickness providing an optical density of 0.6-0.8; the function of the third retroreflective sublayer can be performed by a color-changing layer.

The color and total reflectance of the reflective information-bearing layer (5) formed by these sublayers depends on the thickness and reflectivity of each individual reflective sublayer.

In the optical protective device, the connecting layer is a layer of thermally activated glue with a thickness of 3-3.5 μm and is made of acrylic-based materials.

According to a second aspect of the invention, there is provided a method for manufacturing an optical security device, comprising the steps of: providing a substrate on which a separating layer is applied sequentially, a protective layer, a transparent information-bearing layer (4) carrying at least one holographic image, and / or at least one latent image, and / or a color-changing layer, and a reflective information-bearing layer (5), consisting of at least three reflective sublayers and bearing a visible my image, a connecting layer is applied over the indicated reflective sublayers, while the first and second reflective sublayers are sequentially formed with a predetermined shape and size on at least a portion of the surface of the transparent information-bearing layer (4), and the third reflective sublayer is formed completely over the surface of the transparent information carrier layer (4), while the projection area of the protective, connecting and separation layers on the substrate coincides with the area of the substrate.

In this case, the substrate is made of a transparent polymeric material or a composite material containing a transparent polymeric material with a thickness of 12-50 microns; the separation layer is made of synthetic wax compositions with a thickness of 0.2-0.5 microns; the protective layer is made of one row material: polyvinylidene fluoride, polytrifluorochlorethylene, polycarbonate 1-2 microns thick by intaglio printing; a transparent information-bearing layer (4) is made of materials based on synthetic resins with a thickness of 0.8-1.0 μm.

- 2,026,699

Moreover, according to the method of manufacturing an optical protective device, holographic and / or latent images are provided in a transparent information-bearing layer (4) by direct printing methods: embossing - holographic images, intaglio printing with photoluminescent dyes - hidden images, color-changing layer is applied by flexographic printing and vacuum spraying .

In this case, the first reflective sublayer carrying visible information is made of aluminum by vacuum spraying on top of a transparent information-bearing layer (4), on the surface of the aluminum layer of which the first reflective sublayer is made, an image is printed that matches the holographic image, a lacquer that is stable in alkaline environment, and conduct selective demetallization.

In this case, the second reflective sublayer carrying visible graphic information is made of copper by vacuum spraying on top of the first reflective sublayer, on the surface of the copper layer of which the second reflective sublayer is made, an image is matched with a holographic image, varnish, stable in an alkaline environment, and spend selective demetallization.

And the third reflective sublayer is made of one material of the following series: zinc sulfide, titanium oxide, gold, silver, bismuth oxide on top of the second reflective layer by vacuum deposition; the function of the third retroreflective sublayer can be performed by a color-changing layer.

In this case, the connecting layer is a layer of thermally activated adhesive with a thickness of 3-3.5 μm and is made of acrylic-based materials.

Methods for implementing an optical protective device are spray coating methods, various types of analog and digital printing, UV irradiation systems, cold and hot lamination methods. The means of implementation are printing equipment, printing presses, spraying and spraying installations, inkjet printers, ultraviolet irradiation devices, devices for hot and cold lamination.

Thus, the claimed optical protective device is multivariate, that is, it allows you to create a wide family of protective equipment, in which the use of a full or partial combination of the declared security features, namely: a combination of visible and invisible to the naked eye protection signs formed in a thin transparent information-bearing layer , of an optically variable image formed in a color-changing layer, against a background of a multicolor reflective layer carrying a multicolor image, contains aschee fixed graphical information significantly increases the stability of optical security device against imitation, falsification and antiredeposition and unauthorized use of the protective label.

An advantage of the claimed optical device is that individual layers can combine several functions, for example, a color-changing layer simultaneously with its main function can serve as a third reflective sublayer and, in certain cases, an additional transparent information-bearing layer, and a reflective layer along with its main function performs the function of information -carrier layer.

A high degree of protection against reuse is provided by using the final product in the form of a hot stamping foil, in this case, the protective element is transferred to the surface of the protected object in the form of a thin film 2.5-4 microns thick, which does not contain mechanically strong layers. Any attempt to separate the protective element from the surface of the protected object leads to damage or destruction of the protective element - reuse is not possible.

The choice of materials with different properties allows you to create a protective device with a certain ratio of strength characteristics - interlayer adhesion, brittleness and ductility and create easily deformable labels that cannot be reused. Increasing the resistance against copying and imitation is achieved by including additional protective features in the structure of the protective device: the structure and color of the reflective layer or the transparent holographic layer and / or the transparent color-changing layer.

In addition, the achieved technical result of the claimed invention is the expansion of the technical capabilities of optical security elements, which can serve as evidence of the authenticity of the protected objects, in particular documents, banknotes, securities, stamps of various fees, plastic cards, packaging.

The inventive method has passed industrial tests, during which optical protective devices were obtained in the form of hot stamping foils and self-adhesive labels.

Description of the figures of the drawings

The implementation of the optical protective device is illustrated in FIG. 1-3: FIG. 1 is a schematic diagram of an optical protective device;

FIG. 2 is a plan view of a multicolor structure of a reflective information-bearing layer;

- 3,026,699 FIG. 3 is a cross-section of an optical protective device deposited on the surface of a protected object.

Description of a preferred embodiment of the invention

The optical protective device consists of a combination of sequentially performed layers (Fig. 1):

the substrate 1, which is the carrier of the protective device and made of a transparent polymer material or composite material containing a transparent polymer material with a thickness of 12-50 microns;

a separation layer 2 made of synthetic wax compositions and having a thickness of 0.2-0.5 microns;

a protective layer 3 made of one material of the series: polyvinylidene fluoride, polytrifluorochlorethylene, polycarbonate, 1-2 microns thick;

information-bearing layers carrying basic information, including a transparent information-bearing layer 4, bearing at least one holographic image, and / or at least one latent image, and / or color-changing layer, and made of a transparent polymer material imprinted on at least in part of its surface with at least one holographic image and / or at least one latent image (security signs) made, for example, of photoluminescent dyes, as well as a color An alternating layer consisting of two layers of zinc sulfide and / or of titanium dioxide and / or of bismuth oxide and / or of silver and a dielectric separation layer between them, with all of the above imprinted images and / or layers in area and geometric the shape coincides with the area of the transparent information carrier layer 4, and the shape and dimensions of the dielectric separation layer are the same or different from the sizes and shapes of the transparent information carrier layer 4; and a reflective information-bearing layer 5, carrying visible information formed by three individual reflective sublayers 7, 8 and 9, differing and / or matching in color, geometric shape and size; and the connecting layer 6, which is a layer of thermally activated glue with a thickness of 33.5 μm, made of acrylic-based materials.

Moreover, the projection area of the transparent information carrier layer 4, the protective layer 3, the connecting layer 6 and the separation layer 2 on the substrate 1 coincides with the area of the substrate, and each of the three reflective sublayers 7, 8, 9 is made completely on the surface of the previous layer or on it parts, and the geometric form of execution is the same or different in size and shape from the previous layer.

Materials for the implementation of the substrate 1, the separation layer 2 and the protective layer 3, as well as their thickness were chosen so as to provide, together with other layers of the optical protective device, the specified strength properties.

When the thicknesses of the layers are lower than the values of the above limits for the respective materials, the strength and mechanical characteristics of the protective device are not achieved: the optical protective device is deformed and / or destroyed when used. The implementation of layer thicknesses above the values of the specified limits for the respective materials is impractical due to the achievement of sufficient strength at these values.

A key element of the claimed optical protective device is a reflective information-bearing layer 5, the detailed structure of which is shown schematically in FIG. 1 and 2. A reflective information-bearing layer 5, carrying visible information formed by three individual reflective sublayers 7, 8 and 9 (Fig. 1), also carrying visible information and differing from each other in color, geometric shape and size, consists of:

the first reflective sublayer 7, carrying visible information, made of aluminum with a thickness that provides an optical density of 1.9-2.1; this sublayer having a predetermined shape is provided on a part of the surface of the transparent information carrier layer 4;

the second reflective sublayer 8, carrying visible information, made, as a rule, of copper with a thickness providing an optical density of 0.9-1.1; this layer having a predetermined shape is provided on a part of the surface of the transparent information carrier layer 4 and the sublayer 7, and has a predetermined shape;

the third reflective sublayer 9, made of one material of the following series: zinc sulfide, titanium oxide, gold, silver, bismuth oxide with a thickness providing an optical density of 0.6-0.8; this layer, as a rule, is carried out completely on the surface of the transparent information carrier layer 4 on top of the sublayers 7 and 8, while the dimensions and geometric shape of the third reflective sub layer 9 and the transparent information carrier layer 4 are completely identical. It should be noted that the color-changing layer of the transparent information-bearing layer 4 can optionally perform the function of the third reflective layer.

All three reflective sublayers 7, 8 and 9 are translucent and have different colors, sizes and geometric shapes, overlap or do not overlap, and

- 4,026,699 colors formed by zinc sulfide - 11 (transparent silver), a combination of zinc and aluminum sulfide - 12 (white), a combination of zinc, aluminum and copper sulfide - 13 (light red) and a combination of zinc and copper sulfide - 14 (red ), due to which a multicolor reflective image is formed, as shown in FIG. 2.

The connecting layer 6, which is a layer of thermally activated glue with a thickness of 33.5 μm, is made of acrylic-based materials. The choice of material of the connecting layer 6 is carried out empirically. When performing the thicknesses of the specified layer 6 below 3 μm, communication failures between the layers are observed during the use of the protective agent or its destruction. The thickness of the connecting layer 6 above 3.5 μm is impractical due to the achievement at these values of sufficient bond strength.

According to a preferred embodiment, an optical protective device is obtained as follows.

Carry out the carrier layer, i.e. a substrate 1 of one material of the following row: a transparent polymer material, a composite material containing a transparent polymer material as the basis of an optical protective device.

After that, according to the claimed method, the following layers are successively formed: a separation layer 2 of a wax composition, 0.2-0.5 μm thick, is formed completely on the surface of the substrate 1 by flexographic printing;

the protective layer 3 is performed by the method of flexographic printing from one material of the following series: polyvinylidene fluoride, polytrifluorochlorethylene, polycarbonate with a thickness of 1-2 microns completely over the surface of the separation layer 2;

a transparent information-bearing layer 4, carrying at least one holographic image, and / or at least one latent image, and / or color-changing coating, is made of material based on synthetic resins, this layer is applied completely over the surface of the protective layer 3, and at least one surface of this transparent information-bearing layer 4 is imprinted with at least one holographic image by embossing and / or at least one latent image by intaglio printing olyuminestsentnymi dyes and / or applied color-variable layer capable of changing its color depending on the angle of incidence and optical properties of reflecting and light-transmitting portions. At the same time, the color-changing layer (not indicated) is 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 transparent dielectric separation layer 100-350 nm thick, depending on the desired colors and color shear 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 deposited by thermoresistive vacuum deposition, and the dielectric separation layer is applied either by flexographic printing in the case of organic compositions, or by magnetron vacuum deposition of metal halides.

A reflective information-bearing layer (5), consisting of sublayers 7, 8, 9, is formed as follows:

providing a first reflective sublayer 7, carrying visible information, at least on a surface portion of the transparent information-bearing layer 4, wherein said first reflective sublayer 7 has a predetermined shape and is made of aluminum, and applied by vacuum deposition, print an image consistent with a holographic image, a lacquer that is stable in an alkaline environment, and conduct selective demetallization to give it a predetermined geometric shape and size, agreed holographic image formed on the transparent information-bearing layer 4; providing a second reflective sublayer 8, carrying visible information, at least on a part of the surface of the transparent information-bearing layer 4, carrying a holographic image, while the specified sublayer 8 has a predetermined shape and is usually made of copper; the specified sublayer 8 is applied by vacuum deposition, the image is matched with a holographic image, lacquer stable in an alkaline environment, and selective demetallization is carried out to give it a predetermined geometric shape and size, consistent with a holographic image formed on a transparent information-bearing layer 4 on top of the sublayer 7, and with the form and contents of the sublayer 7, with which the sublayer 8 partially overlaps;

a third reflective layer 9 made of one material of the following series: zinc sulfide, titanium oxide, gold, silver, bismuth oxide; this layer, as a rule, is provided completely over the surface of the transparent information carrier layer 4, the dimensions and geometric shape of the transparent information carrier layer 4 and the sublayer 9 are completely identical, while the third reflective sublayer 9 is applied by vacuum deposition;

as a result, all three reflective sublayers 7, 8 and 9, which are translucent and have different colors, sizes and geometric shapes, overlap and / or do not overlap, when

- 5,026,699 this produces colors formed by zinc sulfide - 11 (transparent silver), a combination of zinc and aluminum sulfide - 12 (white), a combination of zinc, aluminum and copper - 13 (light red) and a combination of zinc and copper sulfide - 14 (red ), due to which a multicolor reflective image is formed (see Fig. 2);

the connecting layer 6, which is a layer of thermally activated glue, made of synthetic polymeric materials on an acrylic basis completely over the entire surface of the optical protective device; this layer is used to attach the protective device to the surface 10 (Fig. 3) of the protected object by hot stamping. In FIG. 3 shows a cross section of an optical protective device deposited on the surface of the protected object, with the substrate 1 and the separation layer 2 being removed during hot stamping and not shown in FIG. 3.

The main objectives of the claimed invention is the provision of a multilevel security device and the protection of the holographic image that is part of the optical security device from imitation and falsification, as well as ensuring the reliability of operational visual control, which are solved by giving the standard reflective layer the function of an information-bearing layer that carries color image consistent with a holographic image, both images (combination of holographic and color reflective) clearly visible to the naked eye. The same applies to hidden security features that make up the optical security device: when rendering a latent image consistent with color reflective, both images (a combination of hidden and color reflective) are clearly visible to the naked eye. Moreover, all color combinations and all combinations of images can change to a different color scheme when the angle of incidence of light changes due to the color transition of the color-changing layer.

The described design of the optical device is resistant to reuse, since any attempt to separate the mark from the surface of the protected product leads to the destruction of the mark. An optical protective device can serve as evidence of the authenticity of the product, since the visible and hidden information contained in the device is unique and cannot be changed, copied, transferred to another product. Operational visual verification is reliable due to the unique combination of coordinated images: holographic, latent, reflective color and color transitions when changing the angle of incidence of light. Visualization of latent images in special lighting conditions and with the help of filters is also an element of protection. Detailed verification - laboratory spectral and microscopic examination of the device.

Industrial applicability

The claimed invention can be used to protect against falsification of valuable documents: passports, vouchers, banknotes, stocks, check books, etc.

Claims (21)

CLAIM 1. An optical protective device comprising a sequentially arranged substrate (1), a separation layer (2), a protective layer (3), a transparent information carrier layer (4), a reflective information carrier layer (5) and a connecting layer (6), wherein the transparent information carrier layer (4) comprises at least one holographic image and / or at least one latent image and / or a color-changing layer; the reflective information-bearing layer (5) contains at least three different, matching in color, size and geometric shape, reflective sublayers provided for at least part of the transparent information-bearing layer (4) in such a way as to ensure the formation of a combined color image . 2. The optical protective device according to claim 1, in which the substrate, which is the carrier of the protective device, is made of a transparent polymeric material or composite material containing a transparent polymeric material with a thickness of 12-50 microns. 3. The optical protective device according to claim 1, in which the separation layer is made of synthetic wax compositions and has a thickness of 0.2-0.5 microns. 4. The optical protective device according to claim 1, in which the protective layer is made of one material of a series: polyvinylidene fluoride, polytrifluorochlorethylene, polycarbonate with a thickness of 1-2 microns. 5. The optical protective device according to claim 1, in which the transparent information-bearing layer (4) is made of a transparent polymer material with a thickness of 0.8-1.0 μm, over the entire surface of which or at least part of it is imprinted by embossing on at least one holographic image, and / or intaglio printing with photoluminescent dyes, at least one latent image, and / or a color-changing layer is applied by flexographic printing and vacuum spraying. 6. An optical protective device according to claim 5, in which a color-changing layer deposited on a transparent information-bearing layer (4) consists of two layers made of at least - 6,026,699 in one of the following series: zinc sulfide, titanium dioxide, bismuth oxide, silver, a dielectric separation layer between them, while the area of two layers, for example zinc sulfide, coincides with the area of the transparent information-bearing layer (4), and the shape of the dielectric separation layer is made equal to or smaller in area in comparison with the transparent information-bearing layer (4). 7. The optical protective device according to claim 1, wherein the first reflective sublayer carrying visible information is made of aluminum with a thickness providing an optical density of 1.92.1. 8. The optical protective device according to claim 1, wherein the second reflective sublayer carrying visible information is made of copper with a thickness providing an optical density of 0.9-1.1. 9. The optical protective device according to claim 1, in which the third reflective sublayer is made of one material of the following series: zinc sulfide, titanium oxide, gold, silver, bismuth oxide with a thickness providing an optical density of 0.6-0.8; the function of the third retroreflective sublayer can be performed by a color-changing layer. 10. An optical protective device according to one of claims 7 to 9, in which the color and total reflectivity of the reflective information-bearing layer (5) formed by these sublayers depends on the thickness and reflectivity of each individual reflective sublayer. 11. The optical protective device according to claim 1, in which the connecting layer, which is a layer of thermally activated adhesive with a thickness of 3-3.5 microns, is made of acrylic-based materials. 12. A method of manufacturing an optical security device, comprising the following steps, according to which a separating layer, a protective layer, a transparent information-bearing layer (4) carrying at least one holographic image, and / or at least one latent image are successively applied to the substrate and / or a color-changing layer, and a reflective information-bearing layer (5), consisting of at least three reflective sublayers and bearing a visible image; a connecting layer is applied over said reflective sublayers, wherein the first and second reflective sublayers are sequentially formed with a predetermined shape and size on at least a part of the surface of the transparent information-bearing layer (4), and the third reflective sublayer is formed completely over the surface of the transparent information-bearing layer layer (4), while the projection area of the protective, connecting and separation layers on the substrate coincides with the area of the substrate. 13. The method according to item 12, according to which the substrate is made of a transparent polymer material or a composite material containing a transparent polymer material with a thickness of 12-50 microns. 14. The method according to item 13, according to which the separation layer is made of synthetic wax compositions with a thickness of 0.2-0.5 microns. 15. The method according to p. 12, according to which the protective layer is made of one material of a series: polyvinylidene fluoride, polytrifluorochlorethylene, polycarbonate with a thickness of 1-2 microns by gravure printing. 16. The method according to item 12, according to which the transparent information-bearing layer (4) is made of materials based on synthetic resins with a thickness of 0.8-1.0 microns. 17. The method according to clause 16, according to which holographic and / or latent images are introduced into a transparent information-bearing layer (4) by direct printing methods: embossing - holographic images, intaglio printing with photoluminescent dyes - hidden images, color-changing layer is applied by flexographic printing methods and vacuum spraying. 18. The method according to item 12, according to which the first reflective sublayer carrying visible information is made of aluminum by vacuum spraying on top of a transparent information-bearing layer (4), on the surface of the aluminum layer of which the first reflective sublayer is made, an image is printed, consistent with a holographic image, varnish, stable in an alkaline environment, and conduct selective demetallization. 19. The method according to p. 12, according to which a second reflective sublayer carrying visible graphic information is made of copper by vacuum spraying on top of the first reflective sublayer, on the surface of the copper layer of which the second reflective sublayer is made, an image consistent with the holographic image is printed, lacquer, stable in an alkaline environment, and conduct selective demetallization. 20. The method according to item 12, according to which the third reflective sublayer is made of one material of the following series: zinc sulfide, titanium oxide, gold, silver, bismuth oxide on top of the second reflective layer by vacuum deposition; the function of the third retroreflective sublayer can be performed by a color-changing layer. 21. The method according to item 12, according to which the connecting layer, which is a layer of thermally activated glue with a thickness of 3-3.5 microns, is made of acrylic-based materials.