RU2379757C1 - Method for protection from counterfeiting and checking authenticity of objects - Google Patents

Abstract

FIELD: physics; marking.

SUBSTANCE: invention relates to counterfeit protection apparatus. The method uses coating material deposited on a section of an object with addition of uniformly distributed chemical elements with concentration n(10^-5-10^-6) g/g, where n=1-9, which are not present in the chemical composition of the coating material. The background X-ray spectrum of the coating material is measured and the range of X-ray energy with minimum background level is determined. Depending on the required degree of protection of the object, the amount of chemical elements added is selected, the energy of X-ray fluorescence lines of which lie in the region of the spectrum with minimum background level and their concentrations are given. The set of the amount of added chemical elements and their concentration is the chemical passport for authenticating the object.

EFFECT: reduced cost of making protective marks with high degree of counterfeit protection.

4 dwg

Description

The invention relates to information storage means designed to protect against counterfeiting of securities, labels and other similar products of mass production, controlled with the help of special devices during random control checks of the turnover of products.

Modern practice of the use of protective technologies conditionally distinguishes three main forms of protection: declared, certified and hidden. Each of these main groups of protective technologies is designed and operates at a certain level of control by the consumer, manufacturer and relevant government agencies. Declared protection implies the availability of the information necessary for the consumer to decide on the authenticity of a product. Such informational support, for example, is advertising. Among other, very obvious methods of open identification of goods, high-tech demetallized holograms on transparent bases can be distinguished. The use of open forms of protection against fraud and illegal trade requires constant and extensive advertising support and legislative support. Certified means of marking goods is a complex of hidden and visible technical measures of protection against falsification, the application technology and method of control of which are known only to the manufacturer of the product and / or the owner of the trademark. The presence and description of such protective measures, as well as the method of their identification, may be a trade secret of the manufacturer (owner of the trademark) or partially disclosed to them in the certificate of security of the product. These methods primarily include various printing technologies (watermark, microtext, thermo- and photochromic additives in dyes), special types of paper materials for labels, hidden methods of labeling products. Hidden methods of entering and reading information embedded in visible protective technologies are also used - microtext in holograms, a hidden bar code, special printing methods. These types of protection, as a rule, are monitored with the help of special devices during random control checks of the turnover of products.

A known method of forming a carrier of protective information (RU 2318677, B23D 15/00, B44F 1/12, publ. 2008.03.10 2008) / 1 /, which is the structure of a polymer material having a relief surface in the form of etched channels in a track membrane filled with a substance . In this case, the etched channels are filled with metal by means of its galvanic deposition, until hemispherical specular metal micro-formations form on the surface of the polymeric material. The hemispherical shape of these micro-formations is established in a reflective optical microscope using either a moving point source of light or in circular illumination of a data carrier with a given number of point light sources. Such a security information medium is difficult to manufacture.

A known method of protection against counterfeiting by applying information identifying tags with its fixation by means of an adhesive layer to the surface of the protected element (RU application No. 2006129804, D21H 21/40, 2008.02.27) / 2 /. A photosensitive bacteriorhodoxin protein is introduced into the adhesive layer, while the identifying label or part of it is made transparent, and the corresponding surface area of the protected object is made with a transparent or mirror-reflective coating. A method for controlling the authenticity of an object is to illuminate a photosensitive element with two light sources with wavelengths, respectively, in the absorption band of the ground and intermediate states of bacteriorhodoxin.

A known protective element and method of its manufacture (RU 2314930, C2, B42D 15/00, B44F 1/12, G09F 3/02, 2008.01.20) / 3 /, having a higher degree of protection against counterfeiting due to easily and clearly distinguishable color effects and variable optical effects, such as a holographic element. However, the known method of marking visually distinguishable graphic images does not have a sufficiently high degree of protection, since it can be copied using printing equipment.

Known printing inks and toners for protective marking and the application of protective labels for the purpose of detection and fakes (RU 2289599, C09B 47 / 04b C07D 487/22, C09B 11/02, G03G 9/09. 2006.12.20) / 4 /. The use of a printing ink composition in anti-counterfeiting technology that includes a charge-generating substance and an environment in which a charge-generating substance has a maximum absorption both in the near infrared region of the electromagnetic spectrum in the range from 700 to 1500 nm and in the visible region of the electromagnetic spectrum in the range from 400 to 700 nm, while the charge-generating substance is a complex chemical compound. Identification of the product or substrate consists in determining the characteristic absorption of the label in the near infrared region. The invention provides effective protection of products or substrates when using printing inks containing, for example, blue or green dyes, the absorption band of which can be shifted to the infrared region and partially mask the absorption properties of the marker. The disadvantages of technology for protection against counterfeiting using a composition of printing ink include a limited range of color solutions. In particular, in the manufacture or labeling of food packaging, labels for alcoholic beverages and other goods to ensure attractiveness, a wider gamut of colors is used, usually at least six colorful compositions.

The closest in technical essence to the claimed invention is a method of protection against counterfeiting and authenticity control of valuable products (RU 2276409 C2, G07D 7/06, G06K 19/14, 2006.05.10) / 5 /, taken as a prototype. To reduce costs during industrial implementation, a passive protective tool of a given structure is formed on the product, which provides the ability to control the availability and authenticity of the said tool by the physical method of analysis of resonance effects during external exposure to it by probing electromagnetic radiation of a given radio frequency and detection of the parameters of certain informative features in the resonant response a protective agent for said external exposure followed by an automatic reset representation for the parameters of these informative features with reference values. As a passive protective agent, a metallized at least three-layer resonant filter structure is used. The microwave frequency is used as the probing radiation, and the characteristic peak values of the frequency response of the direct transmission and back reflection coefficients are used as informative signs. The known method is intended for industrial use, mainly in large-scale production and authorized reproduction of protected products, such as banknotes and other securities, as well as various types of credit documents.

The disadvantages of the prototype method are as follows:

- as a passive protective agent using a metallized at least three-layer resonant filter complex structure;

- the economic feasibility of use is possible only with large-scale production to protect against counterfeiting and authenticity control of especially valuable products;

- the ability to control the authenticity of protected products by a wide range of users with available means of control and identification, which reduces the degree of protection against counterfeiting.

The present invention is to develop a method of protection against counterfeiting and authenticity control of both valuable products and any consumer goods with a high degree of protection.

The technical results of the present invention is to reduce the cost of manufacturing protective labels for both valuable products and consumer goods while providing a high degree of protection against counterfeiting.

The specified technical result is achieved by the fact that in the known method of protection against counterfeiting and authenticity control of products, in which a protective tool of a given structure is formed on the product, which provides the ability to control the presence and authenticity of the said tool by a physical analysis method, detecting the parameters of certain informative signs in the response of the protective tool on the mentioned external impact, followed by automatic comparison of the recorded characteristics with the reference values, the detection means according to the invention are used as a protective agent, a coating material applied to the protected product with the addition of chemical elements evenly distributed in its volume with a concentration of n (10 ^-5 -10 ^-6 ) g / g, where n = 1-9 absent in the chemical composition of the paint material, and the presence and authenticity of the protective agent are controlled by comparing the intensities of the characteristic x-ray radiation in the fluorescence spectra of the atoms of the chemical elements ext in the process of excitation of these spectra in the tested and reference protective means by an X-ray source and registration of the spectra by an X-ray spectrometer with a detection limit of these elements n (10 ^-7 -10 ^-8 ) g / g, where n = 1-9.

Reducing the cost of manufacturing and control of protective equipment is achieved through the use of paints and varnishes used in printing with additives of chemical elements. An unlimited number of variations of combinations of chemical elements and their concentrations and a low detection limit of the used X-ray spectrometer provides a high degree of protection against counterfeiting and authentication of products.

The invention is illustrated by drawings.

Figure 1 presents a block diagram of an X-ray fluorescence spectrometer RSA-001, used for registration and identification of protective labels on products.

Figure 2 presents the background x-ray spectrum of the product without a protective label.

Figure 3 presents the x-ray spectrum of the product with a protective label containing the additive of chemical elements in concentration, in g / g: 2 × 10 ^-5 Cr, 2 × 10 ^-5 Mn, 2 × 10 ^-5 Fe, 2 × 10 ^-5 Co, 2 × 10 ⁻⁵ Ni.

Figure 4 presents the x-ray spectrum of the product with a protective label containing the additive of chemical elements in concentration, in g / g: 3 × 10 ^-6 Fe, 3 × 10 ^-6 Co, 3 × 10 ^-6 Ni, 3 × 10 ^-6 Cu.

The method of protection against counterfeiting and authentication of products is as follows. A product, for example, a self-adhesive label for alcoholic beverages, is coated with a paint, mainly a printing ink cured by ultraviolet radiation, which differs from alcohol and water-soluble inks by higher mechanical and chemical resistance. At least three chemical elements from the range with atomic numbers from 24 (Cr) to 30 (Zn) with a concentration of n (10 ^-5 -10 ^-6 ) g / g, where n = 1-9 g / g, are preliminarily added to the paintwork where n = 1-9. Since UV paints are alcohol-soluble, the addition of chemical elements to the paint composition is carried out by thoroughly mixing these paints with alcohol-soluble compounds in the form of oxides and salts of selected chemical elements. To ensure uniform distribution of chemical elements by volume in one liter of paint and varnish material, the sequential dissolution technique known in chemistry was used, according to which the alcohol-soluble compound of chemical elements was dissolved in a small volume of solvent (isopropyl alcohol) in a concentration of 1-2%, then the resulting solution was added with an EPPENDORF microdoser in a paint and varnish material, which is in a viscous-liquid state in an amount of n (10 ^-2 -10 ^-3 ) g, where n = 1-9 and mix thoroughly. The resulting composition is applied to the product, for example, to self-adhesive paper used in the manufacture of labels for alcoholic beverages, by flexographic printing. The flexographic printing method allows you to transfer the paint composition to the roll material using a polymer printing form. The printing section of the flexographic machine contains a colorful bath with a paint and varnish composition in a viscous-liquid state, a paint pick-up shaft, a linear shaft, on the outer surface of which strokes are applied, providing ink transfer to the polymeric printing form with the necessary graphic image engraved or etched. Self-adhesive paper with a given speed from the electromechanical drive of the printing press moves between the polymeric form with the coating material applied on it and the pressure roller. In this case, the paint material covering the protruding parts of the mold relative to other parts is transferred to the surface of the web material.

The choice of the range of chemical elements with atomic numbers from 24 (Cr) to 30 (Zn) is due to the fact that in the X-ray fluorescence spectra of self-adhesive paper, as well as in the X-ray spectra of the used UV curable inks (UV inks), the analytical region of the spectra in the range energies from 5.4 KeV (K-alpha line of Cr) to 8.64 KeV (K-alpha line of Zn) has a low-intensity background component, which allows elemental analysis in this region with a detection limit of elements at level n (10 ^-7 - 10 ^-8 ) g / g, where n = 1-9.

The presence and authenticity of the protective agent was controlled by an X-ray fluorescence spectrometer RSA-001, with a detection limit of chemical elements of at least 10 ^-8 g / g, which is produced by a pilot production of the Research Institute of Physics of the Southern Federal University. X-ray spectrometer (Fig. 1) contains a small-sized X-ray tube BS-1 (RT) 1 with a Mo anode, the radiation of which is directed to a secondary emitter 2, made in the form of a disk and which is a massive tablet pressed from SrCO ₃ . The controlled product 3 with paintwork 4 is mounted on a holder opposite the input window 5 of the recording energy-dispersive Si (Li) detector 6, connected via interface 7 to a spectrum analyzer 8 based on a personal computer. The PT1-induced radiation of the atoms of the material of the secondary emitter 2 enters the paint coating 4 deposited on the product 3 and excites the characteristic fluorescence x-ray radiation of the atoms of the paint material with the added chemical element of predetermined concentrations, which is formed by the collimator 9 and detected by the detector 6. Pulse signals from the energy dispersive detector 6 enter the spectrum analyzer 8 and on the computer display the spectra of x-ray fluorescence of the paint and varnish are observed material with additives of chemical elements. At the first stage of the implementation of the method of protection and counterfeiting and authentication of products measure the background spectrum of the paint material (figure 2) and determine the energy range of x-ray radiation with a minimum background level. Depending on the required degree of protection of the product, the number of chemical elements introduced into the additive is selected, the energies of the x-ray fluorescence lines of which are located in the spectral region with a minimum background level, and their concentration is set within the range n (10 ^-5 -10 ^-6 ) g / g where n = 1-9. The formed composition of the additive is introduced into the paint material. The paint and varnish material with the additive (protective mark) is applied to a part of the surface of the protected product, which is mounted on the sample holder of the X-ray spectrometer in the corner aperture zone of the detector 6 formed by the collimator 9. After recording the fluorescence spectrum of the protective mark applied to the product, its characteristics are stored in the memory of computer spectrometer kit.

In a specific embodiment of the method, self-adhesive paper manufactured by Fasson, Germany, ink curable by ultraviolet radiation, manufactured by Dupon, Germany, and flexographic printing presses from Focus, Great Britain, were used as a protected product. As follows from figure 2, the background includes an intense line of K-alpha series Ca. The rest of the spectrum in the energy range 4.5–12 keV has a low background component. Therefore, all chemical elements whose K-series X-ray spectral lines are in this energy range can be introduced into the protective label, which allows elemental analysis with a low detection limit. In figure 3, the X-ray spectrum contains lines of the K-series of chemical elements Cr, Mn, Fe, Co, Ni in equal concentrations of 2 × 10 ^-5 g / g, and in figure 4, the lines of the K-series of chemical elements are present in the X-ray spectrum Cr, Mn, Fe, Co, Ni in equal concentrations of 3 × 10 ^-6 g / g. When comparing the spectra of figure 3 and figure 4, which is carried out programmatically in the computer of the spectrometer, you can see the difference in the intensities of the x-ray lines of the spectra of the same chemical elements, but with different concentrations. The combination of the amount of chemical elements introduced into the additive and their concentration is a chemical passport of authenticity of the product. Any deviations from the characteristics of the passport indicate the falsification of the protective label. The performed experiments confirmed the effectiveness of the proposed method of protection and authentication of self-adhesive labels. The estimated cost of manufacturing a protective label by the claimed method is about 0.01 rubles with a circulation of 100 thousand copies, which is three orders of magnitude lower than that of the prototype.

Information sources

1. RU 2318677, B23D 15/00, B44F 1/12, publ. 2008.03.10 2008.

2. RU application No. 2006129804, D21H 21/40, 2008.02.27.

3. RU 2314930 C2, B42D 15/00, B44F 1/12, G09F 3/02, 2008.01.20.

4. RU 2289599, C09B 47/046 C07D 487/22, C09B 11/02, G03G 9/09. 2006.12.20.

5. RU 2276409 C2, G07D 7/06, G06K 19/14, 2006.05.10 - prototype.

Claims (1)

A method of protection against counterfeiting and authenticity control of products, in which a protective tool of a given structure is formed on the product, which provides the ability to control the presence and authenticity of the said tool by a physical analysis method, detecting the parameters of certain informative features in the response of the protective tool to the mentioned external influence, followed by automatic comparison of the registered features with reference values embedded in the memory of the detection means, characterized in that о as a protective agent use the paint and varnish material applied to the protected product with the addition of chemical elements evenly distributed in its volume with a concentration of n (10 ^-5 -10 ^-6 ) g / g, where n = 1-9, absent in the chemical composition of the paint material , and the control of the presence and authenticity of the protective agent is carried out by comparing the intensities of the characteristic x-ray radiation in the fluorescence spectra of the atoms of the chemical elements of the additive in the process of excitation of these spectra in the test and reference protective means by an X-ray source and spectra registration by an X-ray spectrometer with a detection limit of the indicated elements n (10 ^-7 -10 ^-8 ) g / g, where n = 1-9.

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