EA014999B1 - Method for producing photoluminiscent polarisation protective element, a protective element produced by said method, a valuable document comprising said protective element and a method for verifying authenticity of the document comprising protective element - Google Patents

Abstract

The invention relates to counterfeit protection and authentication of valuable documents. According to the invention a method of production photoluminescent polarization protective element is disclosed, a protective element made according to said method, a method of verification the authenticity using said protective element. The method of production photoluminescent polarization protective element comprises the steps of: a) applying a layer of liquid-crystal composition on a surface of a substrate made of anisotropic polymer material having a structured surface, the layer of liquid-crystal composition is structured in the direction coinciding with the direction of structuring the substrate surface, wherein said liquid-crystal composition consists of liquid-crystal monomer adding thereto a polymerization photoinitiator and luminescent dyes, while the orientation of the luminescent dyes molecules coincides with the orientation of the liquid-crystal monomer molecules, b) irradiating at least one portion of said liquid-crystal layer by UV, forming at least one polymerized anisotropic portion of the layer in which a homogenous orientation of molecules both liquid-crystal polymer and luminescent dyes is recorded, c) a layer of the liquid-crystal composition is heated, wherein at least one unexposed portion of the liquid-crystal layer transforms into isotropic state and UV radiation during 1 minute is performed covering the whole surface recording said al least one isotropic portion, thus stipulating forming in the liquid-crystal layer preset combinations from latent image visible in polarized light and latent polarized photoluminescent image, d) applying a protective transparent layer for all surface of the protective element. The document authenticity with the protective element is verified using a mirror reflector and linear polarizer, with visualization of latent image at natural radiation and UV radiation of the protective element.

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.

State of the art

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, hidden images based on colorless embossing and kippeffect, etc., as well as using magnetic, holographic, optical and other methods. Among the security elements with variable optical properties, the most reliable and difficult to reproduce are elements containing hidden security signs that allow multiple operational verification by non-destructive methods, for example, images visible only in polarized light, or photostimulated luminescent images.

The luminescent method of protecting valuable documents using holmium ions and verification methods based on its use are described in I8 patent No. 6503603, publ. 01/07/2003, IPC V41M 3/14; while for the manufacture of a protective luminescent label from a number of rare-earth metal ions, only one is selected, therefore, the level of stability of the proposed anti-imitation agent is not high enough.

The use of at least two substances with photostimulated luminescence in various optical ranges with spectrophotometric verification for the formation of hidden signs of protection is described in international publications XVO 2000/079347 of 12/28/2000, IPC B41M 3/14; AO 2001/042031 dated 06/14/2001, IPC V41M 3/14.

Changing the relative concentrations of luminescent compounds allows you to create the spectral code of the protected document, which is read using a spectrophotometer and compared with the available emission spectrum of the standard luminescent composition for this type of document. The mismatch of the emission spectra of the document being checked and the standard indicates that the security sign and, therefore, the document are fake. The number of different (quantitatively and qualitatively) double or triple chemical compositions and the corresponding optical spectra is unlimited, therefore, the described methods are highly resistant to counterfeiting and imitation, but they are not operational means of protection, as they require special equipment for authentication.

The development of polarization protection in recent years has led to the fact that the methods for forming latent images visible only in polarized light have become very diverse, therefore, the stability of polarized protection against counterfeiting has become not high enough. For example, the formation of a latent polarized image using liquid crystal polymers, for example I86955839, publ. 10/18/2005, IPC V41M 3/14, - a latent polarized image formed by oriented and non-oriented sections of a thin layer of a liquid crystal polymer can be imitated by the cheaper simple and affordable thermomechanical method without using liquid crystals. Therefore, at present, preference is given to combinations of a polarized latent image with other security features.

As can be seen from the consideration of the presented examples of the most popular methods of hidden protection against counterfeiting (polarizing and luminescent), there is a need to create a simple operational tool that does not require verification of special devices, which contains hidden security features, and is highly resistant to counterfeiting.

An optical element consisting of an optically anisotropic layer formed of liquid crystal molecules and containing fluorescent molecules is described in international publication νθ 98/52077 and is proposed as a means of protection against counterfeiting and / or copying. The authors did not use the proposed composition to form a latent polarized image exhibiting an additional photostimulated emission of polarized light in the visible region. This is a significant drawback.

Closest to the claimed protective agent and method of its manufacture is the protective element and the method of its manufacture described in EA 11116 from 12.30.2008, IPC Β41Ό 15/00; protective elements are a polymer layer made of ordinary polymers: polycarbonate, polyvinyl alcohol, fluoropolymers, in which a latent image is visualized in polarized light in the form of separate sections of a layer with induced anisotropy; luminescent dyes, oriented in the anisotropic regions of the layer in such a way that polarized luminescence of anisotropic regions is observed along with non-polarized luminescence of isotropic regions, are additionally introduced into this layer.

The authentication of products marked with this protective label consists in irradiating the protective label with UV radiation in the range of 250-400 nm and observing luminescence through

- 1 014999 rotating polaroid.

Thus, polarized luminescence is used as the main and only protective feature, and not a complex of latent polarized images and the associated polarized luminescence. This is a significant disadvantage of this invention, since the presence of several security features significantly increases the reliability of the security element.

The aim of the present invention is to provide a protective agent with increased resistance against counterfeiting and reproduction, achieved by the optimal selection of the spatial correspondence of the pair: polymer matrix / luminescent dye; a protective agent containing hidden protective features: a latent image visualized in polarized light, and polarized luminescence arising from UV irradiation of the agent, with the possibility of multiple operational and detailed instrumental verification using simple non-destructive methods.

The objective of the present invention is to provide a protective agent with a higher level of protection and with higher levels of reliability and stability of the protective elements against counterfeiting, copying and imitation by forming a protective optical means having a combination of two interlocking hidden security features with a high degree of protection for each of from copying and falsification, both protective features being based on the volume of one common structural element, one of the features being a polarized latent image, and another hidden security feature is photostimulated polarized luminescence.

It is known (N.D. Zhevandrov, Polarized Light. - M .: Publishing House Nauka, 1969) that anisotropic molecules of luminescent dyes are oriented with their long axis along the direction of extension in the anisotropic matrices of polymers and emit polarized light with natural (unpolarized) light luminescence. Similarly, linearly polarized photoluminescence of dyes arises isomorphically incorporated into the crystal lattice with a lower order symmetry than cubic. A similar effect — linearly polarized photo-stimulated emission of dyes in an ordered liquid crystal matrix — was discovered by us in the proposed systems. Visualization of hidden security features is carried out without the use of special sophisticated equipment, the necessary devices are a linear polarizer and a compact low-power ultraviolet lamp.

The protective agent according to the invention is made of materials that have high mechanical, chemical, radiation resistance and stability over a wide temperature range, which ensures high stability of all the protective features included in the element.

SUMMARY OF THE INVENTION

According to a first aspect of the invention, there is provided a method for manufacturing a photoluminescent polarizing protective agent, comprising the steps of:

a) a layer of an LCD composition 1-5 mm thick, which is structured in the direction coinciding with the direction of structuring the surface of the substrate, is applied onto the surface of the substrate from an anisotropic polymeric material having a structured surface, wherein said layer of the LCD composition consists of an LCD monomer with the addition of a polymerization photoinitiator and luminescent dyes, while the orientation of the luminescent dye molecules coincides with the orientation of the molecules of the LCD monomer;

b) irradiate with UV radiation in the range 200-400 nm for 20-30 s at a temperature of the layer of the LCD composition from about 60 to about 90 ° C with a surface power of 0.5 mW / cm ² radiation through a mask of a given configuration at least one area the specified layer of the LCD composition and form at least one polymerized anisotropic section of the layer in which a uniform orientation of molecules of both the LC polymer and the molecules of the luminescent dyes is fixed;

c) the layer of the LCD composition is heated to about 135-145 ° C, at least one unexposed portion of the LCD layer becomes isotropic, and the entire surface of the layer of the LCD composition is repeatedly irradiated with UV radiation for 1 min, thereby fixing at least one of said isotropic regions, thereby causing the LCD layer to form predetermined combinations of a latent image visible in polarized light and a latent polarized photoluminescent image;

g) apply a protective transparent layer over the entire surface of the protective agent.

In this case, the substrate is made of a material that is completely transparent or partially reflecting light, or may be a transparent hologram.

In addition, the radiation that excites the luminescence of dyes introduced into the layer of the LC composition lies in the range of 200-400 nm.

In this case, the visualization of a latent image formed by anisotropic and isotropic sections of the polymer layer is carried out in linearly polarized light using a mirror reflector and a linear polarizer.

In addition, according to the method of the present invention, the visualization of a latent image generated by polarized photoemission of anisotropic sections of the layer and unpolarized photoemission of isotropic sections of the layer is carried out using a rotating linear polarizer with simultaneous exposure to UV radiation.

The substrate for the protective agent is made of an anisotropic polymeric material, which is a transparent lavsan.

The thickness of the substrate is 12-23 microns, preferably 19 microns.

It should be noted that the simplest materials for the formation of thin anisotropic layers containing oriented luminescent pigments are widespread commercially available polymer films produced by extrusion from a number of polyolefins, polyesters, fluoropolymers and some others.

Another promising class of polymer materials for forming the proposed protective agent are liquid crystal polymers. Orientation methods for LCD molecules are diverse and well known.

Molecules of luminescent dyes can be introduced into such LC polymer films during their manufacture by adding small amounts of dye to the mixture for irrigation on an oriented surface of the substrate. The result is an anisotropic system — a luminescent dye included in a uniaxially anisotropic polymer matrix — to form latent images in which it is necessary to violate the anisotropy of the layer in at least one portion of the anisotropic polymer layer. The simplest known method is the local heating of the polymer matrix above the temperature of the nearest phase transition of the used specific LC polymer. In this case, at least the segmental mobility of the polymer molecules is thawed, which leads to disordering of the anisotropic crystal structure and, as a rule, to a decrease in the birefringence and the degree of orientation of the included dye molecules. Local heating can be carried out either using a thermal printer (thermomechanical action), or using an infrared laser with a digital beam scan or exposure through a mask.

One of the LC materials for forming an ordered optically anisotropic polymer layer is a composition consisting of a liquid crystal monomer, a polymerization photoactivator and a luminescent additive. Various dyes exhibiting photoluminescence in the blue, green, and red spectral regions are used as luminescent additives.

In this case, the ordered liquid crystal phase can be formed in the classical way: a layer of a mixture of LC monomers with a thickness of about 1-20 μm is formed on the surface of a transparent substrate - a polymer film pre-treated with an aqueous solution of polyvinyl alcohol and unidirectionally rubbed with a cloth. In this case, the maximum effect is obtained - the maximum birefringence and the possibility of forming sufficiently thick (about 20 μm) oriented films. A sufficient value of Δη in films with a thickness of 1-5 μm is obtained using an orienting surface — an extruded polymer film that has not undergone a special structuring treatment. It should be noted that in the absence of a structuring surface treatment, the effect is observed, although much weaker, which is apparently due to the intrinsic weak anisotropy of the surfaces of polymer films subjected to mechanical tension during extrusion. Among other things, this allows the use of high-performance printing equipment for direct printing of latent images in a continuous process. This is how the initial oriented texture is obtained in thin films. Then, after evaporation of the solvent, irradiation of the obtained film with UV light through a mask led to the polymerization of monomers in an oriented state in the regions determined by the configuration of the mask with a high birefringence (Δη ~ 0.2). After heating above the bleaching temperature, unirradiated and, therefore, nonpolymerized sections of the film pass into an isotropic melt with Δη = 0. Subsequent irradiation of the entire layer of the LCD mixture allows you to capture a latent image.

According to a second aspect of the invention, there is provided a protective device adapted for subsequent incorporation into a protected object in the form of a valuable document or banknote and comprising a polymer substrate with a structured surface and an LC composition layer disposed on it containing isotropic and anisotropic sections formed thereon forming predefined combinations of a latent image visible in polarized light, and latent polarized photoluminescent image, and protective transparent with Second, applied to the entire surface of the security device that mechanically protects the surface of the protective means and optical masks and hides little visible difference isotropic and anisotropic areas.

According to a third aspect of the invention, there is provided a valuable document containing a protective agent made in accordance with the claimed method described above, which is a banknote, voucher, certificate, passport, plastic card.

According to a fourth aspect of the invention, there is disclosed a method for verifying the authenticity of a document with a security measure according to the second aspect of the invention, using hidden visualization

- 3 014999 polarized images, a mirror reflector and an optical linear polarizer, comprising the steps according to which:

a) place the document with a protective agent on the mirror reflector, while the linear polarizer is placed on top of the document;

b) they observe the document in visible light through the polarizer, providing a visualization of a latent image formed by a combination of isotropic and anisotropic sections of the protective agent, while the image is formed in the form of sections with different optical density and contrast depending on the angle of rotation of the optical polarizer;

d) the document with the protective agent is irradiated with UV radiation and the document is monitored through an optical polarizer in UV light, causing the luminescence of the luminescent dyes that make up the layer of the LCD composition of the protective agent to provide a visualization of the latent image formed by a combination of isotropic and anisotropic regions, this image is formed in the form of sections with different brightness depending on the angle of rotation of the polarizer;

e) determine the authenticity of the document with a protective agent by the simultaneous presence of a visualized latent image obtained in steps b) and d).

In this case, the document subject to verification is a valuable document, which is a voucher, certificate, plastic card, banknote or plastic banknote.

It should be noted that the visualization of hidden security features is carried out without the use of special sophisticated equipment, the necessary devices are a linear polarizer and a compact low-power ultraviolet lamp. The main element, carrying both hidden security features, consists of sections of the layer forming both hidden images. Some sections are isotropic, their birefringence is zero, they do not interact with polarized light and do not change its wave structure. Others, anisotropic, have nonzero birefringence (Δη> 0). Thus, when the polarizer rotates against the background of isotropic sections, the optical density of which does not depend on the angle of rotation, anisotropic sections of the latent image are observed, the optical density of which depends on the angle of rotation of the polarizer, this is the first hidden security feature. The second hidden security feature: illumination of the protective element with non-polarized short-wave radiation excites light emission, and the isotropic sections emit an isotropic glow, the brightness of which when viewing the protective element through a linear polarizer does not depend on the angle of rotation, while the ordered anisotropic sections emit a polarized glow, brightness which depends on the angle of rotation of the polarizer. Thus, when examining the photostimulated emission of a protective element through a linear polarizer, a self-luminous latent polarized image is observed.

Description of the figures of the drawings

The features, elements and advantages of the invention result from the following description of embodiments of the invention with reference to the accompanying drawings, in which FIG. 1A-D show the basic principle of recording latent images;

in FIG. 2 shows a method for visualizing a latent polarized image formed by oriented anisotropic and non-oriented isotropic sections of a polymer matrix;

in FIG. 3 shows a method for visualizing a latent photostimulated polarized image formed by regions containing oriented and non-oriented molecules of luminescent dyes.

Description of a preferred embodiment of the invention

A description of the photoluminescent polarizing protective agent and the method of its manufacture will be described with reference to FIG. 1-3. As an illustrative example, a liquid crystal protective agent has been selected.

According to a method for manufacturing a photoluminescent polarizing protective agent, the surface of the substrate 2 (Fig. 1A) is made of a transparent anisotropic polymeric material having a structured surface, for example a transparent lavsan 12–23 µm thick, preferably 19 µm, with sufficient surface anisotropy.

In addition, transparent polymers can be used, requiring, unlike lavsan, additional processing (for example, felt treatment) to obtain a structured surface in the desired direction.

In addition, the substrate may be made of a material partially reflecting light, or be a transparent hologram, which introduces the effect of additional protection for the claimed protective agent and increases the external attractiveness of the protective agent.

In the manufacture of security products with hidden images to protect against counterfeiting of valuable documents, it is preferable to use high-performance printing equipment for direct printing of hidden images in a continuous process. For these purposes, it is necessary to form

- 4 014999 an LCD polymer film with an anisotropy providing an Δη value sufficient for the subsequent process of visualization of latent images in a film of 1-5 μm thick, which is obtained when using, as a substrate, in particular, a structured lavsan surface that does not require special treatment to obtain anisotropic surface properties.

It is necessary to dwell separately on the stage of applying to the surface of the substrate 2, made as an illustrative example of lavsan, layer 1 of the LCD composition with a thickness of 1-5 μm, for example, by gravure printing. The use of other printing methods is also possible.

In this case, the layer 1 of the LCD composition spontaneously is structured in the direction coinciding with the direction of the structuring of the surface of the specified substrate 2, which is due to the nature of the specified LCD layer. The specified layer 1 of the LCD composition consists of an LCD monomer 3 with the addition of a polymerization photoinitiator and luminescent dyes 4, while the orientation of the molecules of the luminescent dyes 4 coincides with the orientation of the molecules of the LCD monomer 3 (see Fig. 1A).

The main component of polymerizable LCD compositions are liquid crystal molecules containing terminal double bonds. Such LCDs are widely represented on the market. In this case, the products used by Megg are used - reactive mesogens. To obtain the above-described LC layer, special photopolymerizable compositions based on nematic diacrylate KM257 (Megsk) and photoinitiator 1dasige 651 (1-3 wt.%, Preferably 2 wt.%) Were developed. To prevent unwanted uncontrolled thermal polymerization, ~ 0.5% of an inhibitor based on phenol or hydroquinone derivatives was added to the mixture. Various dyes were used as luminescent components, showing luminescence in the blue, green, and red spectral regions: Orlyum white 470, Orlyum white 520, Lumogen 59; used concentrations of up to 1 wt.%, preferably 0.7 wt.%.

Further (Fig. 1B), the LCD layer is irradiated with UV light for 20-30 s at a layer temperature of about 60-90 ° C with a surface power of 0.5 mW / cm ² through a mask 5 of a given configuration, and irradiation is carried out according to at least one portion of said LCD layer 1, whereby at least one polymerized anisotropic portion 6 of layer 1 of the LCD composition with Δη> 0 is formed, see FIG. 1B, in which the homogeneous orientation of both the LC monomer molecules and the luminescent dye molecules is fixed.

Then, layer 1 of the LCD composition is heated to a temperature of about 135 to 145 ° C, while all unexposed portions of layer 1 of the LCD composition go into an isotropic melt 7 'with Δη = 0, see FIG. 1B, and under the influence of UV radiation for 1 min on the entire surface of the layer 1 of the LCD composition, the indicated isotropic sections 7 'of the melt are fixed in the form of polymerised sections 7, see FIG. 1G, in which the molecules of the LC polymer formed as a result of photopolymerization and the luminescent dye molecules are randomly, randomly, thus causing the formation in layer 1 of the LCD composition of predefined combinations from a latent image visible in polarized light and a latent polarized photoluminescent image. Apply a protective transparent layer 10 (Fig. 2) over the entire surface of the protective agent.

Thus, a polymer film is obtained that carries two types of latent images. Depending on the configuration of the mask 5, photopolymerization creates a complex configuration of latent images formed of isotropic sections 7 and anisotropic sections 6, which are clearly distinguishable in polarized light. If necessary, this film (layer) can be separated from the substrate 2 and used to protect various valuable objects.

Visualization of the latent image formed by isotropic 7 (Δη = 0) and anisotropic 6 (Δη> 0) sections of the LCD polymer film 1 (layer of the LCD composition) is carried out using a mirror reflector 9 and a linear polarizer 8 (Fig. 2). A film carrying a latent image is laid on a mirror reflector 9, for example a metal reflector, a linear polarizer is placed on top of the film 8. Visible light 11 passes through a linear polarizer 8, turns into a linearly polarized one, which, passing through isotropic sections of the latent image, does not change amplitudes, since Δη = 0; when polarized light passes through the anisotropic parts of the latent image, the wave structure of the light changes, its amplitude becomes dependent on the angle of rotation of the polarizer. As a result, the observer 12 sees an image consisting of regions with different optical density and contrast (isotropic regions 7 are lighter, anisotropic regions 6 are darker), which depend on the angle of rotation of the linear polarizer 8.

Visualization of a latent image formed by anisotropic sections 6 with oriented molecules of a luminescent dye and isotropic sections 7 with non-oriented molecules of a dye is performed (see Fig. 3) upon excitation of the luminescence of the dyes that make up the composition of the LC composition with UV light and the observation obtained by such the way of photoluminescence using a linear polarizer 8. In this case, the isotropic sections 7 emit isotropic radiation, regardless of the angle of rotation of the polarizer 8, while the anisotropic s 6 portions emit polarized light whose brightness depends on the rotation angle of the polarizer 8.

- 5 014999

As a result, the observer 12 sees a luminous image formed from areas with different brightness and contrast, which depend on the angle of rotation of the linear polarizer 8.

The simultaneous presence of these two protective features in the form of an image obtained when observing through a linear polarizer in natural light, and an image obtained when observing through a linear polarizer when the protective agent is irradiated with UV radiation, indicates the authenticity of the product, which includes this protective agent.

Industrial applicability

The claimed invention can be used to protect against counterfeiting of valuable documents, which are a transparent plastic card, banknote or plastic banknote, and to identify the authenticity of these documents.

Claims (17)

CLAIM 1. A method of manufacturing a photoluminescent polarization protective agent, comprising stages on which: a) put on the surface of the substrate of anisotropic polymeric material having a structured surface, a layer of LCD composition, which is structured in the direction coinciding with the direction of structuring the surface of the substrate, with the specified layer of the LCD composition consists of an LCD monomer with the addition of a photoinitiator of polymerization and fluorescent dyes, while the orientation of the molecules of luminescent dyes coincides with the orientation of the LC monomer molecules; b) irradiating with UV light through a mask at least one portion of the specified anisotropic layer of the LC composition and form at least one polymerized anisotropic portion of the layer in which the homogeneous orientation of the molecules of both the LCD polymer and the molecules of the luminescent dyes is fixed; C) heat the layer of the LCD composition, with at least one unexposed area of the layer of the LCD composition goes into an isotropic state, and re-irradiate the entire surface of the layer of the LCD composition with UV light for 1 min, while fixing at least one the specified isotropic area, thus causing the formation in the layer of the LCD composition of pre-defined combinations of the latent image, visible in polarized light, and the latent polarized photoluminescent image; g) put a protective transparent layer over the entire surface of the protective agent. 2. The method according to claim 1, in which the substrate is made of a material that is completely transparent or partially reflecting light. 3. The method according to claim 1, in which the substrate is a transparent hologram. 4. The method according to claim 1, in which the polymerization of the layer is carried out under the action of UV radiation in the range of 200-400 nm. 5. The method according to claim 1, in which the dye introduced into the layer of the LCD composition, luminesces under the action of UV radiation in the range of 200-400 nm. 6. The method according to claim 1, in which the visualization of the latent image formed by the anisotropic and isotropic sections of the polymer layer, is carried out in a linearly polarized light using a mirror reflector and a linear polarizer. 7. The method according to claim 1, in which the visualization of the latent image formed by polarized photoemission of anisotropic areas of the layer and non-polarized photoemission of isotropic areas of the layer is carried out using a rotating linear polarizer with simultaneous exposure to UV radiation. 8. The method according to claim 1, in which the layer of the LCD composition is performed with a thickness of 1-5 microns. 9. The method according to claim 1, in which the substrate is made of anisotropic polymeric material, which is a transparent polyester. 10. The method according to claim 1 or 9, in which the thickness of the substrate is 12-23 μm, preferably 19 μm. 11. The method according to claim 1, wherein in step b) at least one portion of the liquid crystal composition layer is irradiated with UV light for 20-30 seconds at a layer temperature from about 60 to about 90 ° C with a surface power of 0, 5 mW / cm ² radiation. 12. The method according to claim 1, in which re-irradiation of the layer of the LCD composition is carried out at a temperature of the specified layer of about 135-145 ° C. 13. The method according to claim 1 or 11, in which the mask used when irradiating with UV radiation from at least one portion of the LCD composition layer has a predetermined configuration. 14. Protective means adapted for subsequent embedding into the protected object in the form of a valuable document or banknote and containing a polymer substrate with a structured surface and an LCD composition layer placed on it containing isotropic and anisotropic regions formed on it forming predetermined combinations of the latent image, - 6 014999 visible in polarized light, and hidden polarized photoluminescent image and a protective transparent layer deposited on the layer of the LCD composition; and made according to the method according to one of claims 1 to 13. 15. Valuable document containing protective equipment made according to the method according to one of claims 1 to 13, and representing a banknote, voucher, certificate, passport, plastic card. 16. The method of verifying the authenticity of a document with a protective agent according to claim 14, using for imaging hidden polarized images a mirror reflector and a linear polarizer, containing the steps according to which: a) place the document with protective means on the mirror reflector, while the linear polarizer is placed on top of the document; b) observing the document in visible light through a polarizer, providing visualization of the latent image formed by a combination of isotropic and anisotropic sections of the protective agent, while the image is formed as sections with different optical density and contrast depending on the angle of rotation of the polarizer; d) irradiate the document with UV protection and protect the document through a polarizer in UV light, causing the luminescence of luminescent dyes that make up the LCD composition of the protective composition with visualization of the latent image formed by a combination of isotropic and anisotropic areas, the image is formed in the form of areas with different luminosity depending on the angle of rotation of the polarizer; d) determine the authenticity of the document with a protective agent by the simultaneous presence of the visualized latent image obtained in steps b) and d). 17. The verification method of claim 16, wherein the document to be verified is a valuable document representing a voucher, certificate, plastic card, banknote, or plastic banknote.