EA011116B1 - Safety element, method for producing thereof, protecting mark containing it and method of identification article genuineness marked by the protecting mark - Google Patents

Abstract

The invention relates to matters used for identifying authenticity of articles, in particular, to a safety element comprising latent luminous images characterized by polarized and nonpolarized radiation and can be used for producing protective marks applied on documents, banknotes, securities, cards, labels, etc. The present invention is aimed at developing a new safety element characterized by high protection level against counterfeit. Another task of the claimed invention is to develop a new protecting mark marking articles' genuineness comprising a new protective element and providing higher protection level from a counterfeit. There also proposed a method for producing a new safety element and a method of identification articles' genuineness, marked by the new protecting mark. The inventive feature is solved by designing a new safety element for identification articles' genuineness comprising personal information in the form of latent luminous image with polarized and nonpolarized radiation, as well as by developing a protecting mark comprising said safety element.

Description

The invention relates to materials used for authentication of products, in particular, to a security element containing latent luminescent images characterized by polarized and non-polarized radiation, and can be used in the manufacture of security tags applied to documents, banknotes, securities, labels, labels etc. items.

Protective elements are known in which a photoluminescent segment is used having polarized luminescence and polarized absorption. So in US patent No. 7108286, 2006 describes a protective element containing a luminescent dye distributed in the polymer carrier. The specified protective element may be made in the form of a film, strip thread, etc. When the document containing the specified protective element is irradiated with ultraviolet radiation, and when the luminescence of the protective element is visualized through a rotating polaroid, a change in the luminescence intensity of the protective element is observed. The advantages of such a protective element are that it is almost impossible to imitate. However, registration of the polarized luminescence of a filament or strip deposited on paper, and especially the degree of polarization of the luminescence of such an element, requires special equipment. In addition, these security features can be reused.

It is also known that the effect of polarized luminescence in thin polymer layers can be achieved in various ways. One way to obtain such systems is the introduction of the corresponding luminescent organic or inorganic dyes into the oriented polymer before or after the orientation stage (1.1. Iekketb, Siet. Ryuk. Le !!., Yo1. 19, pp. 517-523 (1973); b .U.La (aha) ap e! A1., Siet. Ryub. Le !!., Wo1. 95, pp. 525-528 (1983); K. Biei e! A1., Co11o1b & Po1uteg 8c1epse, Wo1. 263, pp. 392-395 (1985); M. wap Sigre e! A1., 1. P1ut. 8sk, Paradise B, P1uteg Ryubsb. Wo1. 26, pp. 1613-1625 (1988); Υ. Όίτίχ e! A1., Masgoto1esi1eb, Uo1. 30, pp. 2175-2177 (1997); I8 Ra! en! 456953).

Another convenient method is the orientation of the luminescent polymer dye during irreversible thermomechanical deformation of the polymer layer. The selected fluorescent material must be an elastic polymer or an elastic mixture of a polymer or oligomeric fluorophore with a base polymer (C. Ζΐιηημ е! А1., 8п111. Ме!., Уо1. 46, pp. 235-242 (1992); 1. My1 ! op e! a1., Po1uteg, Wo1. 33, pp. 2340-2348 (1992); R. Iutek1eu e! a1., Abu. Ma! eq., Wo1. 7, pp. 43-44 (1995); and. Bettet e! a1., Arp1. Ryub. Bey., Wo. 68 pp. 3007-3009 (1996); I8 Ra! en! 5204038; 1. My1! op e! a1., 1. Ro1ut. δα. , Ro1ut. Ryub. Eb., Uo1. 30, pp. 871-878 (1992)).

An alternative is to obtain polarized luminescent layers by oriented buildup of luminescent, as a rule, polymeric materials on oriented polymeric and (or) inorganic substrates or surfaces (I8 Pa! Ep! 5180470; K. Ryuet e! A1., 8up111. Me!., Uo1. 55-57, pp. 454-459 (1993); Ό. Reidask e! A1., 1. Maeeg 8sk, Uo1. 31, pp. 915-920 (1996); K. C111, e! A1. , Α6ν. Ma! Eg., Yo1. 9, pp. 331-334 (1997), S. Yybbet e! A1., Ys. | Knock!., Yo1. 21, pp. 903-907 (1996), R.1. Reagay e! A1., Arp1. Ryuk. Le !!. Yo1. 62, pp. 729-731 (1993)).

Also known (Eurasian patent No. 004750, 2004) are protective labels containing latent polarizing images formed in the polymer layer in the form of sections with anisotropic properties (prototype). The main advantages of such tags are the impossibility of copying them, the simplicity and speed of authentication using a cheap visualizer, however, to achieve comprehensive protection, additional security elements must be present in the tag.

The present invention is to develop a new security element, characterized by a high level of protection against counterfeiting.

Another objective of the claimed invention is the creation of a new security label for marking genuine products, containing a new security element and providing an increased degree of protection of marked products from counterfeiting.

Another objective of the claimed invention is a method for manufacturing a new security element and a method for identifying the authenticity of products marked with a new security tag.

The problem is solved by creating a new security element for identifying the authenticity of products containing individual information in the form of a hidden luminescent image with polarized and non-polarized radiation, as well as by creating a security label that includes the specified security element.

According to the claimed invention, the protective element is a polymer layer containing a luminescent dye, while in the polymer layer a latent image is visualized in polarized light in the form of separate sections of the layer with induced anisotropy, and the luminescent dye is oriented in these anisotropic sections of the layer so that with ultraviolet irradiation, polarized luminescence of anisotropic regions is observed along with nonpolarized luminescence of isotropic regions in the layer.

When observing the luminescence of this protective element through a rotating polaroid, individual sections of the polymer layer appear in the form of blinking segments on a constantly dim background and form predetermined images in the form of a picture, logo, text, etc.

The basis of this invention is the assumption that with a certain selection of the system

- 1 011116 polymer-luminescent dye, it is possible to obtain a luminescent layer having local areas with polarized luminescence in the places where a latent polarization image is formed in this layer according to the known method described in PCT / VU2005 / 000005 dated 06/09/2005, where the polymer layer is localized and luminescent dye, respectively.

It was found that the main condition for obtaining the effect of polarized luminescence in anisotropic regions of the polymer layer is the selection of luminescent dyes in such a way that, due to the peculiarities of its structure, maximum interaction with the macromolecules of the polymer layer is achieved by the type of dipole-dipole or other Van der Waals, or covalent interaction. In addition, dye molecules must have a linear, extended, conjugated system of π bonds, which is also a necessary condition for achieving the effect of dye polarization luminescence.

According to the invention, polymers for the manufacture of the polymer layer can be used, in particular, copolymers of vinylidene fluoride with tetrafluoroethylene, polyvinyl alcohol, polycarbonates.

The different chemical structure of the polymer base used to obtain layers containing latent polarization images, as well as the mutual solubility of the dye polymer, allows the use of the following luminescent dyes:

where the groups X and (or) Υ are, but not only, Η, ΝΗ ₂ , ΝΗ-alkyl, X (alkyl) ₂ , ΟΝ, 8О ₃ Н, 8Θ ₃ Ν; · ι. OH, Oalkyl, (OCH ₂ ) _p O-alkyl, P, C1, Br, groups A and (or) B are aromatic and (or) heterocyclic, but not only chromophore fragments of the following structure:

about

where I can be, but not only, H, Ar, alkyl, (OCH ₂ ) _p O-alkyl; Κι is, but not only, Η, ΝΗ ₂ , ΝΗ alkyl, ^ alkyl) ₂ , CK, 8OD 8O ₃ NO OH, O-alkyl, (NRSCO-alkyl, P, C1, Br.

In a preferred embodiment, a polymer layer of 2-6 microns thick is used, and the concentration of the luminescent dye with respect to the polymer is from 0.01 to 5 wt.%, Preferably 0.1-1 wt.%.

The change in the luminescence intensity of the anisotropic sections of the polymer layer, which is recorded upon observation through a rotating polaroid, can be described approximately by the following expressions:

Ιι = 1 / 2Ι _ο -λ1 _ο = Ι _ο (1/2-λ)

Ι _Π = 1 / 2Ι _ο + λ1 _ο = Ι _ο (1/2 + λ) where Ιι and Ι _ΙΙ are respectively the luminescence intensity of the anisotropic sections of the polymer layer when observed through a polaroid oriented orthogonally to the direction of the orientation of the luminescence polarization Ι ₁ and parallel to the direction of orientation of the luminescence polarization Ι _ΙΙ ;

Ι _ο is the integrated luminescence intensity of isotropic sections of the layer;

λ is the degree of orientation of the dye molecules.

Thus, for layers with a high degree of orientation of the luminescent dye molecules, a change in the luminescence intensity of dye molecules in anisotropic regions is clearly observed at different positions of the polaroid with respect to the luminescent polymer layer.

To establish the authenticity of the described protective element (expert control) using

- A special device is used that contains a source of ultraviolet radiation to excite the luminescence of the dye in the polymer layer, and a rotating polaroid to control the luminescent image formed by the polarized and non-polarized luminescence of the dye.

The second object of the present invention is a method of manufacturing a protective element, comprising preparing a polymer solution, preparing a solution of a luminescent dye in a solvent compatible with the polymer solution, mixing said solutions, forming an isotropic polymer layer with the dye dissolved in it, the dye concentration being the polymer layer is 0.01-5 wt.%, preferably 0.11 wt.%, the formation of a latent image in the resulting layer and the subsequent it, if necessary, removing the substrate.

In a preferred embodiment of the inventive method, a polymer solution is prepared with a polymer concentration of 10-20 wt.%, Preferably 12-16 wt.%, The thickness of the polymer layer is 26 μm, preferably 3-5 μm.

As the substrate can be used PET film, 1111 film, PVC film, preferably a thickness of 12-60 microns.

Another object of the invention is a security label, including the specified security element and attached to the genuine product for marking.

The inventive security label in addition to the security element may contain a reflective layer deposited on a substrate or directly on the protected product. The presence of a reflecting layer enhances the brightness of the luminescence and, accordingly, the image quality of the luminescent dye formed by oriented regions, in addition, it allows us to fix a latent polarization image formed in the polymer layer by anisotropic sections of the polymer layer, which is also a protection element.

As a reflective substrate, paper or a polymer film can be used, which is provided with a reflective layer in the form of a sprayed metal or reflective ink, a layer of a printing, holographic or metal foil, etc. In addition, the reflective layer can be applied directly to the product to be protected - a label, fabric label, control mark, etc. The reflective layer can be opaque or translucent.

To attach the protective tag to the marked product, glue is applied to the tag or marked product. In this case, the choice of glue is determined by the purpose of the protective mark and corresponds to the technology of applying the protective mark.

In the case of expert verification of the authenticity of the security label, a special device is used that contains a source of ultraviolet radiation to excite the luminescence of the dye in the polymer layer and a rotating polaroid to control the luminescent image formed by the polarized and non-polarized luminescence of the dye. If operational authentication is required, the security tag can be additionally equipped with a polaroid as a device for visualizing a latent polarizing image.

A method for identifying the authenticity of products marked with the claimed security label consists in irradiating the security label with UV radiation in the range of 250-400 nm and observing luminescence through a rotating polaroid.

Thus, for the first time, a protective element is proposed that contains individual information in the form of a latent luminescent predetermined image with polarized and non-polarized radiation, implemented in a polymer layer up to 6 microns thick, and a protective label based on it. Forgery of such a protective element is extremely difficult and therefore unlikely, and if it is used for the manufacture of a self-destructible protective label, its reuse is excluded. In addition, the use of a reflective layer as an additional component in the security label allows one to obtain a combined protection containing a hidden polarization image, which can be easily checked using a cheap visualizer, as well as a hidden luminescent image with polarized and non-polarized radiation for expert verification.

The following examples illustrate the invention without limiting its scope.

Example 1. The manufacture of a protective element.

Prepare a solution of a copolymer of tetrafluoroethylene with vinylinne fluoride in acetone. The concentration of the polymer is 20 wt.%. Ethyl acetate was then added and the polymer concentration was adjusted to 16% by weight. The dye 4,4-bis - ((E) -2- (5-heptyl-1,3,4-oxadiazole-2-2yl) vinyl) biphenyl is dissolved in methylene chloride

and added to the polymer solution in an amount providing a polymer: dye ratio by weight of 100: 0.5. The resulting solution was thoroughly mixed until homogeneous. The application of an isotropic polymer layer with a dye on a 40 micron thick polypropylene base film is carried out on a machine

- 3 011116 for applying thin layers of Ν \ νί .'- 400. using a spiral anilox roll at a speed of 50 m / min, the temperature of the dryers is 60-80-100 ° C. Get a polymer layer with a dye with a thickness of 2-3 microns.

The formation of local anisotropic sections (latent image) in the polymer layer is carried out according to the method. described in PCT / ΒΥ 2005/000005 dated 09.06.2005.

Example 2. The manufacture of a protective label.

Using a protective element. made in the conditions of example 1. rolling the protective element onto a self-adhesive paper with a reflective coating and removing the flake is carried out on a Ν \ νί .'-400 machine using glue of the grade Eekhso1-518 (Uakrat Sotrotaboi) and a section for lamination. After cutting down on the finishing machine and removing the flash, protective marks of the required shape are obtained. containing latent polarization image and latent image. formed by polarized and non-polarized luminescence of the dye. whose pattern is the same.

Example 3. The manufacture of a protective label.

A solution of polyvinyl alcohol in water is prepared by heating. polymer concentration 16 wt.%. The dye (E) -6.6- (ethen-1.2-diyl) bis-3- (4-methoxy-6- (phenylamino) -1.3.5-triazin-2-ylamino) benzenesulfonic acid sodium salt is dissolved. B-OMe. Β-ΝΗΡ6

in water and added to the polymer solution in an amount. providing a ratio of polymer: dye by weight 99: 1. The resulting solution was thoroughly mixed.

The application of an isotropic polymer layer with a dye on a PET film base with a thickness of 20 μm is carried out on a machine for applying thin layers K ^ C-400. using a pyramidal anilox shaft. at a speed of 25-30 m / min. the temperature of the dryers is 120-130-140 ° C. The temperature of the solution during application is 6080 ° C. Get a polymer layer with a dye with a thickness of 3-4 microns.

The formation of local anisotropic sections (latent image) in the polymer layer is carried out according to the method. described in the application PCT / ΒΥ 2005/000005 dated 09.06.2005.

After this, the polymer layer with the dye is transferred to a suitable self-adhesive material using glue. Protective labels of the desired shape are made using a plotter or punching machine. The resulting labels contain a hidden luminescent image. formed by polarized and non-polarized luminescence of the dye.

Example 4

Prepare a solution of brand polycarbonate in methylene chloride. polymer concentration 17 wt.%. The dye 4.4-bis (5- (4- (2- (2- (2-butoxyethoxy) ethoxy) ethoxy) phenyl) -1.3.4-oxadiazol-2yl) biphenyl is dissolved

in methylene chloride and added to the polymer solution in an amount. providing a polymer: dye ratio of 100: 1.5 by weight. The resulting solution was thoroughly mixed.

The application of an isotropic polymer layer with a dye to a PET base film with a thickness of 30 μm is carried out on a K ^ C-400 thin layer machine. using a pyramidal anilox shaft. at a speed of 55-60 m / min. the temperature of the dryers is 50-80-90 ° C. Get a polymer layer with a dye with a thickness of 3-4 microns.

The formation of local anisotropic sections (latent image) in the polymer layer is carried out according to the method. described in PCT / ΒΥ 2005/000005 dated 09.06.2005.

Rolling the polymer layer onto a self-adhesive aluminum foil and removing the flake is carried out on a machine Νν ^ 400. using glue of the Eekhso1-518 brand (Uakrat Sotrotaboi) and a section for lamination. After cutting down on the finishing machine and removing the flash, protective marks of the required shape are obtained. containing latent polarization image and latent image. formed by polarized and non-polarized luminescence of the dye. whose pattern is the same.

Visualization (control) of the latent polarization image is carried out using an affordable cheap identifier. applying it to a protective mark. Hidden image. formed by polarized and non-polarized luminescence of the dye. register. using a special device. which allows luminescence to be observed through a rotating polaroid during UV irradiation.

Claims (15)

CLAIM 1. A security element for identification of authenticity of products, which is a polymer layer in which a hidden image visualized in polarized light is formed as separate sections of a layer with induced anisotropy, characterized in that a luminescent dye is additionally introduced into this layer, oriented in the anisotropic portions of the layer such that, under ultraviolet irradiation, polarized luminescence of anisotropic regions is observed along with unpolarized luminescence of isotropic chastkov. 2. The element according to claim 1, characterized in that it is made of a polymer selected from the group including copolymers of vinylidene fluoride with tetrafluoroethylene, polyvinyl alcohol, polycarbonates. 3. The element according to claim 1, characterized in that the luminescent dye is selected from the following phosphors: where the groups X and / or Υ are, but not only, Η, ΝΗ ₂ ,-alkyl, AND (alkyl) ₂ , ΟΝ, 8О ₃ Н, 8О ₃ №. OH, Oalkyl, (OCH ₂ ) _n O-alkyl, B, C1, Br, groups A and / or B are aromatic and / or heterocyclic, but not only, chromophore fragments of the following structure: where B may be, but not limited to, H, aryl, alkyl, (OCH ₂ ) _n O-alkyl; B ₁ is, but not only, Η, ΝΗ ₂ , ΝΗ alkyl, ^ alkyl) ₂ ,, ZONE 8О ₃ No., He, O-alkyl, (OCH ^ O-alkyl, B, C1, Br. 4. The protective element according to claims 1 to 3, in which the concentration of the luminescent dye relative to the polymer is from 0.01 to 5 wt.%. 5. The protective element according to claim 4, in which the concentration of the luminescent dye relative to the polymer is 0.1-1 wt.%. 6. A method of manufacturing a protective element according to claim 1, comprising preparing a polymer solution, preparing a luminescent dye solution in a solvent compatible with the polymer solution, mixing these solutions, forming an isotropic polymer layer on the substrate from the resulting dye solution, and dye concentration in the polymer layer is 0.01-5 wt.%, preferably 0.1-1 wt.%, the formation in the resulting layer of the latent image and the subsequent, if necessary, removal of the substrate. 7. The method according to claim 6, characterized in that a polymer solution is prepared with a polymer concentration of 1020 wt.%, Preferably 12-16 wt.%. 8. The method according to p. 6, characterized in that the thickness of the polymer layer is 2-6 microns, preferably 3-5 microns. 9. The method according to claim 6, in which the substrate can be used PET film, II film, PVC film, preferably 12-60 microns thick. - 5,011,116 10. Protective label for marking genuine products and protecting them from forgery, including a protective element according to claims 1-6. 11. Protective label for marking genuine products and protecting them from forgery, containing a protective element according to claims 1-6, a reflective layer and, if necessary, a substrate. 12. Protective label according to claim 11, in which the reflective layer is made translucent. 13. Protective label according to claim 11, characterized in that the substrate is a paper or a polymer film. 14. The label according to claim 11, characterized in that the reflective layer is made of sprayed metal, reflective paint, printing, holographic or metal foil. 15. A method for identifying the authenticity of products marked with a protective label according to claims 10-14, which consists in irradiating the protective label with UV radiation in the range of 250-400 nm and observing luminescence through a rotating polaroid.