EA026971B1 - Security element with a concealed polarized colour image - Google Patents

Abstract

The invention is related to the field of protection of valuable documents against unauthorized access. The invention provides a security element comprising, arranged in succession, a reflecting metallized substrate 2, at least two anisotropic polymer layers 1, one side of each of at least two anisotropic polymer layers 1 having a respective reflecting isotropic data-carrying layer 3 including at least one blank area 4, the remaining surface of said data-carrying layer including metallized image areas 5, and further comprising a protective layer provided on top of the successively arranged layers, wherein the first anisotropic polymer layer 1 is adapted to be applied directly to the reflecting metallized substrate 2, and succeeding anisotropic polymer layers 1 with reflecting isotropic data-carrying layers 3 are applied successively to each other; at least one blank area 4 of at least two reflecting isotropic data-carrying layers is adapted to be filled with a layer 6 of material having isotropic absorbing or absorbing-reflecting optical properties varying in accordance with a preset law; at least one blank area 4 of the data-carrying layer 3 in one anisotropic polymer layer 1 is disposed in a preset manner relative to at least one blank area 4 of the data-carrying layer 3 of the adjacent anisotropic polymer layer 1 to provide obtaining of concealed multi-colour images with mixed colour hues and/or multi-colour images including fragments of half-tone colour image when viewed in white polarized light.

Description

The present invention relates to the field of development of marking means for identifying various objects and products. More specifically, it relates to methods and systems for detecting product authenticity based on the use of protective elements with hidden, invisible in natural white light, grayscale color images.

State of the art

Currently, one of the main global problems is the protection against counterfeiting of various products of the trading industry and intellectual property, as well as banknotes, securities, credit cards, documents, works of art, etc. This forces the world community to develop a variety of methods and devices for identifying and protecting against counterfeiting the above elements and products.

Of great interest are protective elements that, under certain conditions, exhibit anisotropy of their optical properties at the visualization stage when identifying and determining the authenticity of the product.

In patent publications (I8 4659112; I8 5284364; I8 5389698; I8 6100967; I8 6124.970; OV 2328180; KN 2165360) anisotropic protective elements are proposed based on the use of one-sided metallized polymer films with hidden labels formed in their volume that are invisible in the natural white light and visualized by polarized radiation. The possibility of such visualization is due to the fact that the optical properties at the locations of the marks and the background differ in magnitude of birefringence, for example, birefringent background and isotropic marks, or vice versa.

In the first case, initially anisotropic, uniaxially oriented, for example, by the method of mechanical stretching of the film are used, and isotropic marks are formed by the mechanical method (I8 5284364), thermomechanical (I8 4659112) or photochemical (I8 6124970); (I8 5389698), for example, laser (OV 2328180) disorientation of polymer macromolecules.

The disadvantage of protective elements with the indicated labels is their lack of heat resistance. In addition, the thermal method does not provide a high spatial resolution and, therefore, the recording density of information in such protective elements.

In the second case, initially isotropic, non-oriented polymer films are used, obtained, as a rule, by irrigation from solution, and anisotropic rasterized marks are formed by the method of thermomechanical formation of local internal stresses at the locations of the rasterized marks during rapid local heating and cooling of polymer layers, see the international publication \ νϋ 2006/00514 9, publ. 01/19/2006; Patent EA 010035, publ. 06/30/2008.

Anisotropic protective element is known from the prior art, based on the use of one double-sided metallized birefringent polymer film with a metallized reflective mask (information layer) formed on the surface of one of its sides with hidden demetallized marks (spaces) that are invisible in natural white light and visualized in clear contrasting image, for example, painted in dark blue on a white background when viewed in circularly polarized light (EA 200801396 (A3), published on October 30, 2008; international publication νθ 2009154506, published on December 23, 2009, the patent holder of which is NPO Kripten OJSC (Russia).

The closest known protective elements in terms of their technical nature and the achieved results are, selected as a prototype, an anisotropic protective element based on the use of at least two double-sided metallized anisotropic polymer films with metallized films formed on the surface of one of the sides of each of the polymer films reflective masks (information layers) with hidden transparent demetallized spaces, invisible in natural white light and visa lysed using polarized white light in the form of a multicolor image, see international publication νθ 2012143746, publ. 10/26/2012; V. A. Shevko, Security labels with color covert polarized images, THe 8-1P 1p1egiioioia1 SoyGeheise NOEOCHRO-2011, 29 §er1eshEg-1 OSYuSg. M1I5k, Be1agi8, proposed by A.T.V. Batech.

In fact, the security element disclosed in international publication VO 2012143746 with a hidden polarized multicolor image, its production method and visualization method basically implements a combination of two previously known methods for producing hidden polarized images:

a method of obtaining a latent polarized multicolor image disclosed in patent 1, 'δ 2393968, publ. 02/05/1946, in which a stack of sequentially superimposed homogeneous in thickness thickness oriented oriented anisotropic polymer films with optical axes parallel to each other and lying in their plane is used, each of these films being cut out with a certain geometric shape corresponding to a certain color of the formed multicolor image and their spatial distribution corresponds to a latent polarized one-color image;

- 1,026,971 a method for producing a latent polarized one-color image disclosed in Eurasian application EA 200801396 A2, publ. 10/30/2008, in which a uniformly oriented oriented anisotropic polymer film is sandwiched between a continuous, fully reflective metallized layer and a metallized reflective background layer with completely transparent spaces, the geometric shape and spatial distribution of which corresponds to a latent polarized one-color image;

The disadvantage of a reflective security element with a hidden polarized multicolor image disclosed in the international publication \ UO 2012143746 is the impossibility of forming hidden polarization images, the number of color gradations in which would exceed the number of birefringent polymer films in the security element and / or in which at least one image color would be made in the form of halftones.

In particular, when forming multi-color images in the CWO (red, green, blue) format with three polymer films and, accordingly, with three information layers, it is impossible to obtain images with a number of color gradations greater than the number of superimposed polymer films, multi-color images with mixed for example, K + O, O + B, K + B or K + O + B in color shades or grayscale images.

This disadvantage significantly limits the protective capabilities of the anisotropic element itself.

SUMMARY OF THE INVENTION

The claimed invention seeks to eliminate these drawbacks and provides a security element with a high multi-level degree of protection against unauthorized use, which is achieved by the development of an improved design of the security element with the possibility of forming security elements with hidden polarized multi-color images with a number of color gradations in excess of the number of optically anisotropic polymer used in it films, including those with mixed, for example, K + O, O + B, K + B or K + O + B tones and / or in which at least one color of the image was made in the form of halftones.

In order to achieve the indicated technical result, a security element is proposed, which comprises successively arranged: a reflecting metallized substrate, at least two anisotropic polymer layers, while on one side of each of at least two anisotropic polymer layers there is a corresponding reflecting isotropic information-bearing layer with at least one whitewash section made therein, and the remaining surface of said information-bearing layer is a reserve bonded metallized areas, and additionally containing a protective layer in the form of a lacquer layer, provided on top of successively located these layers, the first anisotropic polymer layer is made with the possibility of direct deposition on a reflective metallized substrate, and subsequent anisotropic polymer layers with reflective isotropic information-bearing layers are sequentially applied to each other at the same time, at least one gap section is filled with a layer of material with locally varying in accordance with a predetermined law isotropic absorption or absorption-reflective optical properties, and at least one white space of the information-bearing layer in one anisotropic polymer layer is located in a predetermined manner relative to at least one white space of the information-bearing layer of the adjacent anisotropic polymer layer, providing hidden multicolor images with mixed color shades and / or multi-color images images including fragments of a grayscale color image when viewed in polarized white light.

The security element according to the invention is attached to the object to be protected by means of an adhesive layer that is applied to the surface of the reflective metallized substrate, which faces the object to be protected.

In addition, in the protective element, at least two anisotropic polymer layers are made in such a way that their optical axes are parallel to each other, and these layers themselves impart anisotropic optical properties to whitespace portions of the corresponding reflecting isotropic information-bearing layers.

Moreover, in the security element according to the invention, at least one gap section of at least one reflecting isotropic information-bearing layer is filled with a layer of material with isotropic absorbing optical properties that are locally changing according to a predetermined law and / or at least one gap section of one reflecting isotropic the information carrier layer is filled with a layer of material with isotropic absorption reflectors locally changing according to a predetermined law optical properties.

At the same time, at least one whitespace portion is spatially uniformly filled with a layer of material with isotropic absorption or absorption-reflective optical properties that are locally changing according to a predetermined law.

- 2 026971

Moreover, in the protective element according to the invention, a layer formed in the gap areas with locally varying isotropic optical properties according to a predetermined law is made of the same metallized material as the reflecting metallized substrate.

In addition, the protective element may additionally contain a relief information layer in the form of a mirror-reflecting relief-bearing hologram or a diffraction grating element with white spaces and personally perforated transparent pits, which is located between the protective layer and the most remote from the reflecting metallized substrate, reflecting an isotropic information carrier layer.

Moreover, each of the isotropic information-bearing layers of the protective element has a predetermined configuration of arrangement and the number of blank areas and sealed sections, respectively, different from other isotropic information-bearing layers.

In addition, at least one latent polarized multicolor image obtained by examining a security element in polarized white light is presented as a grayscale photograph, and also has a number of color gradations greater than the number of anisotropic polymer layers.

Moreover, hidden polarized multi-color images with mixed, for example, K + O, O + B, K + B or K + O + B color shades when viewed in polarized white light are provided within the area occupied by white areas.

Brief Description of the Drawings

The essence of the invention, consisting in a description of the features, technical elements and its advantages, is illustrated by examples of specific, but not limiting the claimed technical solutions, embodiments with reference to the accompanying drawings, in which:

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

FIG. 2 - spatial distribution of the absorption value A = £ (x, y) in the areas of the sealed metallized section 5 and one of the gap sections 4, filled with a layer without material with absorbing optical properties locally changing according to a given law, one of the isotropic information-bearing layers (3 )

The implementation of the invention

The above and other problems of the prior art are solved by methods in accordance with the examples described in the present invention.

In FIG. 1 shows a cross section of the proposed protective element, which consists of successively arranged: reflecting metallized substrate 2 and at least two anisotropic polymer layers 1, while on one side of each of at least two anisotropic polymer layers 1 is provided a reflective isotropic information carrier layer 3, in which at least one gap portion 4 is made, and the rest of the surface of said layer 3 is a sealed metallized portion 5, with one a a nizotropic polymer layer 1 is deposited directly on one surface of the reflecting metallized substrate 2, and subsequent anisotropic polymer layers 1 with reflecting isotropic information-bearing layers 3 are sequentially applied to each other. It should be noted that an adhesive layer (not shown) with the possibility of attachment to the object to be protected is applied to another (back) surface of the reflecting metallized substrate 2. And on top of the sequence of anisotropic polymer layers 1c with reflective isotropic information-bearing layers 3, a protective layer (not shown) in the form of a lacquer layer is applied.

Moreover, these anisotropic polymer layers (1) are birefringent and are designed in such a way that their optical axes are parallel to each other. As mentioned above, each of the isotropic information-bearing layers (3) consists of at least one white space 4, and the rest of its areas are sealed (background) metallized areas 5 (hereinafter referred to as sealed areas 5). Moreover, each of the isotropic information-bearing layers 3 has a predetermined configuration of arrangement and the number of blank sections 4 and sealed sections 5, respectively, different from other isotropic information-bearing layers 3, respectively.

At the same time, at least one of the gap sections 4 is filled with a layer 6 of material with isotropic absorption or absorption-reflective optical properties that are locally varied according to a predetermined law, and the remaining gap sections 4 that are not filled with layer 6 are transparent. Thus, on the surface of, for example, the first information-bearing layer 3, at least one gap section 4, which is transparent, and at least one gap section 4, filled with a layer 6 of material with absorbing optical properties 6 and at least one gap section filled with a layer 6 of material with absorbing-reflective optical properties, and at least one gap section filled with a layer can be placed on the surface of an adjacent information-bearing layer 3 6 m from a material having optical absorptivity properties, the amount and type of filling blank areas 4 in each of the information-bearing layers 3 is selected proiz- 3 026 971 driver.

It should be noted that the configuration of the location and the number of blank sections 4, as well as the type of filling (absorbing or absorbing-reflective material or unfilled i.e. completely transparent) in the aggregate of successively arranged information-bearing layers 3 with the corresponding anisotropic polymer layers 1 is determined by the manufacturer specified protective element and provides a unique, multi-color, almost irreproducible image when viewed in polarized white light.

At the same time, the presence of at least two identically oriented (optical axes parallel to each other) anisotropic polymer layers (1) located behind the corresponding isotropic information-bearing layers (3) (when observed from the extreme information-bearing layer 3, attaches to all white space (4) anisotropic optical properties and allows them to be visualized when observed in polarized white light.

According to the invention, all information-bearing layers 3 have a flat surface and carry protection in the form of latent color images.

The structure of the security element between the isotropic information-bearing layer 3 farthest from the reflecting metallized substrate (2) and the protective layer may additionally include a relief information layer (not shown), which may have a relief surface in the form of a mirror reflecting relief hologram or a diffraction grating element in in the form of personally perforated (demetallized) transparent pits.

Moreover, all information-bearing layers 3, including an additional relief-information layer (not shown) are formed relative to each other so as to ensure the formation of a combined image when viewed in polarized white light, providing a high level of protection.

Information-bearing layers (3) are carriers of hidden information, and a relief-information layer (not shown) in the form of a mirror-reflecting relief-carrying hologram or diffraction-grating element additionally carries a visually visible holographic protection, while perforated (demetallized) transparent pits formed for example, by local laser ablation of a mirror-reflecting hologram or diffraction element before the operation of applying a protective lacquer layer to it, information about tional protection of the protected object.

In contrast to the optically anisotropic protective element disclosed in the international publication \ νϋ 2012143746, which is the closest analogue of the claimed invention, in which unsealed blank areas are made completely transparent, in the proposed technical solution according to the invention in at least one of the isotropic information-bearing layers 3 the space within the location of at least one of the unsealed areas, i.e. the gap section 4, is filled with a layer 6 of a substantially amorphous isotropic material with absorbing optical properties locally changing according to a certain (given) law with an absorption coefficient A = £ (x, y), where x and y are the spatial coordinates in the plane of the isotropic information-bearing layer 3 or an amorphous isotropic material with absorption-reflective optical properties with a reflection coefficient K = \ | / (xy). where x and y are the spatial coordinates in the plane of the location of the isotropic information-bearing layer 3, and ψ is the spatial distribution function of the reflection coefficient. At the same time, the presence of transparent gap sections 4, i.e. blank spaces of the blank 6, along with blanks 4 filled in the above manner.

In FIG. 2 as an example, the spatial distribution of the absorption value A = £ (x, y) is conventionally shown by a dashed line in the regions of the sealed metallized portion 5 and the gap portion 4 filled with a layer 6 of material with absorbing optical properties of one of the isotropic bearing layers 3. From FIG. Figure 2 shows that the amount of absorption in the visible region of the spectrum (for white light) of such an isotropic information-bearing layer 3 in the space section 4, filled with a layer 6 of material with absorbing optical properties that locally changes according to a given law, varies from almost 0 to 100% to a certain law A = £ (x, y).

According to the invention, it is also assumed that the absorption coefficient can be uniform, but less than 100% within the entire area of such a gap portion 4, filled with a layer 6 of material with isotropic absorption or absorption-reflective optical properties that are locally varied according to a predetermined law, in depending on the specific location of a given gap section 4 in the corresponding isotropic information-bearing carrier layer 3 of the protective element. Thus, the law of changing the optical properties in the gaps is set by the manufacturer, and thus introduces an additional unique level of protection for the product to be protected, which is almost impossible to reproduce.

- 4,069,971

Such a construction of the security element described above with layers 6 formed within the area occupied by the whitespace 4 of the corresponding isotropic information-bearing layers 3, when visualized, for example, by a linear or circular polarizer 8, enables the formation of light beams of a polarized multicolor image in which at least one color made in the form of halftones or in the form of mixed multi-color, for example, K + O, O + B, K + B or K + O + B (K - red, O - green. B - blue) color shades and Luton.

When the protective element is irradiated with natural white light from the side of the protective layer for the observer, no multicolor image effect occurs.

However, when viewing the specified protective element in polarized white light, if a linear or circular polarizer 8 is placed in front of the protective element, the white light passing through the polarizer 8 to the protective element becomes polarized and already polarized light, passing through a sequence of at least two anisotropic polymer layers (1) with information-bearing layers 3 with space sections 4 located in a given configuration, and reflected from the sealed sections 5 and / or from the reflecting metal of the coated substrate 2, and repeatedly passing through the gaps 4 of the information-bearing layers 3 with the anisotropic polymer layers 1, the result is a multicolor polarized image in which at least one color is made in the form of halftones or in the form of mixed multicolor, for example, K + О, О + В, К + В or К + О + В (К - red, О - green, В - blue) of color shades and halftones.

Moreover, in FIG. 1, arrows C1, C2, and C3 denote the colors of the beams, for example, C1 - B (blue), C2 - O (green), C3 - K (red), formed by passing polarized white light through at least two polymer layers 1 and corresponding information -carrier layers 3 with transparent whitespace (4) i.e. blank spaces 4 not filled with layer 6, through which, when visualized, for example, by a circular polarizer 8, light beams C1, C2, and C3 pass twice, reflected from sealed (background) sections (5) or from a reflecting metallized substrate (2), respectively. Their number may not exceed the number used in the protective element of the specified polymer layers 1.

Tsfon - when visualizing a multicolor image, its color is determined by the quarter-wave plate used in the circular polarizer 8, taking into account its chromaticity (the dependence of the birefringence of anisotropic polymer layers on the wavelength), depending on the polymer material used in it.

C4 - there is a semitone, for example, from the color C1 (Fig. 1), depending on the absorbing properties of a particular layer 6 of the gap section 4, through which the light beam C4 passes twice, reflected from the sealed (background) section (5) of one information-bearing layer 3.

C5 - there is a semitone, for example, from the color C1 and a mixture of colors C background, C1 and C2 (Fig. 1) in a certain quantitative ratio, depending on the birefringent properties of the quarter-wave plate of the circular polarizer 8 and the absorbing-reflecting properties of each of the whitespace sections 4 with layers 6 from a material with absorbing-reflective optical properties through which the light beam C5 passes twice.

The possibility of forming protective elements with hidden polarized multicolor images in which at least one color of the image was made in the form of halftones is realized, since each of the polymer layers 1 has the same thickness and birefringence across the entire surface, and the total optical path visualizing white light, passed through the gaps 4, filled with a layer 6 made, for example, of a substantially non-reflective, amorphous isotropic absorbing material (layer 6) and reflected from the completely reflecting metallized substrate 2 or from the sealed portions 5 of the reflecting isotropic information-bearing layers 3 is also the same over the entire cross section of spatially modulated absorption areas 4. Consequently, the color of the light beam emerging from reading from an external linear or circular polarizer 8 in such gaps 4, is also uniform and is determined only by the total value of the optical path traveled, and the brightness of such a monochrome beam in At the intervals of the white space 4 is determined only by the spatial distribution of the absorption value A = £ (x, y) of each unsealed white space 4 with the absorbing layer 6 of information-bearing layers 3 located in the local places of the reading (visualizing) beam.

Depending on the purpose of the proposed security element, the geometric shape of the gaps 4 of each of the reflective, isotropic information-bearing layers 3, corresponding to a certain single-color fragment of a hidden multi-color image, can have a given individual appearance with a size from the order of fractions of microns to several millimeters or more, and their the total number and spatial arrangement on the information-bearing layers 3 may completely or not completely coincide for neighboring anisotropic polymer layers 1 In this case, the optical thickness of each of this anisotropic polymer layer 1 is equal to the product of its thickness by the amount of birefringence at a certain wavelength of the visualizing radiation.

- 5,069,971

The total optical thickness of the individual fragments of at least two anisotropic polymer layers (1), coinciding with the location of the gap sections 4 of these information-bearing layers 3, is selected so that the transmittance T _sum . for white light (not shown in Fig. 1), twice passing through an external, for example, circular or linear polarizer 8 and these fragments of the protective element reflected from the reflecting metallized substrate 2 or from the sealed (background) sections 5 of the corresponding information carrier layer 3, had a maximum at a given wavelength corresponding to a certain color of the latent image.

In the case of using a material with locally varying isotropic absorption-reflective optical properties A = £ (x, y) and Κ = ψ (. \. Ν) locally for the formation of layer 6 in at least one blank section 4 of the information carrier layer 3, the spatial distribution of the reflection value and, accordingly, the transmittance within the region of the location of this gap section 4, varies according to a predetermined law. This allows you to get a protective element with a visually hidden polarized multicolor image made with mixed, for example, K + O, O + B, K + B or K + O + B color, including grayscale shades within the area occupied by certain white spaces 4 It should be noted that the reflective metallized substrate 2 is formed solid and may have a thickness in the range of about 0.02-0.05 microns. It can be formed by, for example, thermal vacuum metallization of one of the materials: A1, Au, Cu, Cr, Νί, Τι and the like.

The key functional layers of the protective element proposed in the present invention are anisotropic polymer layers (1), which are metallized on both sides. In addition, these layers (1) are uniformly oriented birefringent and photo- and thermochemically stable layers. As such anisotropic polymer layers (1), one can use various mono- or biaxially oriented films transparent in the visible and UV regions based on mechanically stretched or extruded polymers, for example, polyvinyl acetate, ethylene-vinyl alcohol copolymer, ethylene-vinyl acetate copolymer , polyethylene terephthalate, vinyl polymers, acrylic polymers, polydienes, polyimides, polyamides, siloxanes, polyvinyl alcohol and others. In such oriented layers, the polymer chains of macromolecules are oriented, as a rule, along the direction of extension or extrusion, as a result of which they become optically anisotropic, which can be observed in white polarized light, for example, in crossed polarizers.

The specified effect obtained, which consists in the formation of a polarized multicolor image in which at least one color is made in the form of halftones or in the form of mixed multicolor ones, for example K + O, O + B, K + B or K + O + B (K - red , О - green, В - blue) of color shades and halftones, is provided by the nature of anisotropic polymer layers 1, which are equally oriented, i.e. their optical axes are parallel, the magnitude of their birefringence, as well as the location of these layers 1 behind the corresponding isotropic information-bearing layers 3, which, when observed from the side of the polarizer 8, gives all the white areas 4 anisotropic optical properties, as well as absorbing or absorbing reflective optical properties of the layers 6 filling gaps 4, and of course the nature of the used polarizer 8.

The practical implementation of the present invention can be carried out in the form of a multicolor latent thread using strips made on the basis of silver paint with absorption varying in cross section from almost 0% in the center of the strip to almost 100% at its edges.

Industrial applicability

The claimed security element can be used to protect against counterfeiting of various products of the trading industry and intellectual property, as well as banknotes, securities, credit cards, documents, works of art, etc.

Of course, that the described options and forms of implementation are for illustrative purposes only and that various modifications and variations of examples and forms of implementation are possible.

Claims (15)

CLAIM 1. A protective element comprising a sequentially arranged reflective metallized substrate, at least two anisotropic polymer layers, while on one side of each of the at least two anisotropic polymer layers there is provided a corresponding reflective isotropic information-bearing layer with at least one a white space, and the remaining surface of the specified information-bearing layer is a sealed metallized areas, and additionally containing a protective a layer provided on top of these layers in series, wherein the first anisotropic polymer layer is capable of being directly applied to a reflecting metallized substrate, and subsequent anisotropic polymer layers with reflecting isotropic information-bearing layers are sequentially applied to each other, at least one gap portion is filled with a layer of material with isotropic absorption or reflective optical properties, wherein at least one gap portion of the information carrier layer in one anisotropic polymer layer is arranged in a predetermined manner relative to at least one gap region of the information carrier layer of the adjacent anisotropic polymer layer, providing hidden multicolor images with mixed color shades and / or multi-color images, including fragments of a grayscale color image when viewed in white polarized light. 2. The security element according to claim 1, which is adapted to be attached to the object to be protected by means of an adhesive layer. 3. The protective element according to claim 1 or 2, in which the adhesive layer is provided on the surface of the reflective metallized substrate facing the object to be protected. 4. The protective element according to claim 1, in which the protective layer is a varnish layer. 5. The protective element according to claim 1, in which at least two anisotropic polymer layers are made in such a way that their optical axes are parallel to each other, and these layers themselves give anisotropic optical properties to the whitespace of the corresponding reflective isotropic information-bearing layers. 6. The protective element according to claim 1, in which at least one blank area of at least one reflecting isotropic information-bearing layer is filled with a layer of material with isotropic absorbing optical properties that are locally varying according to a predetermined law. 7. The protective element according to claim 1, in which at least one blank area of one reflective isotropic information-bearing layer is filled with a layer of material with isotropic absorption-reflective optical properties that are locally changing according to a predetermined law. 8. The protective element according to claim 1, in which at least one gap portion of one reflective isotropic information-bearing layer is configured to fill with a layer of material with isotropic absorption optical properties that are locally varied according to a predetermined law and at least one gap portion of said information carrier layer is made with the possibility of filling a layer of material with locally varying according to preliminary law isotropic absorption-reflective optics eskimi properties. 9. The protective element according to one of claims 1, 6, 7, 8, wherein said at least one gap portion is spatially uniformly filled with a layer of material with isotropic absorption or absorption-reflective optical properties that are locally varying according to a predetermined law. 10. The protective element according to claim 1, in which a layer formed in the gap areas with locally varying isotropic optical properties according to a predetermined law is made of the same metallized material as the reflecting metallized substrate. 11. The security element according to claim 1, which further comprises a relief information layer in the form of a mirror reflecting relief hologram or a diffraction grating element with whitespace and personally perforated transparent pits, which is located between the protective layer and the most reflective isotropic information layer that is farthest from the reflecting metallized substrate -carrier layer. 12. The security element according to claim 1, in which each of the isotropic information-bearing layers has a predetermined, different from other isotropic information-bearing layers arrangement configuration and the number of blank areas and sealed sections, respectively. 13. The security element according to claim 1, in which at least one latent polarized multicolor image obtained by examining the security element in white polarized light is presented in the form of a grayscale photograph. 14. The security element according to claim 1, in which at least one latent polarized multicolor image obtained by examining the security element in white polarized light has a number of color gradations greater than the number of anisotropic polymer layers. 15. The security element according to claim 1, in which, within the area occupied by the whitespace, hidden polarized multicolor images with mixed, for example, K + O, O + B, K + B or K + O + B color shades when viewed in white polarized light.