RU2568708C2 - Multi-layer polymeric protective element - Google Patents

Abstract

FIELD: printing.

SUBSTANCE: invention relates to polymeric multilayer products, in particular to polymeric protective elements used for visual authenticity control of security printing products, such as securities, banknotes, passports and ID documents. The element for authenticity control of security printing products is applied to the substrate and has modified paint areas resulting from exposure to laser radiation on the paint layer to form the image detectable by visual control. The paint layer comprises microparticles ranging in size from 1 micron to 100 microns, coated by thin-film transparent, half-transparent or interference paint layers or microvoids containing pigments or dyes in them. The said microparticles or microvoids are arranged regularly and oriented. The images formed by modified paint areas are made by the laser radiation incident on the paint layer at different angles.

EFFECT: enhanced counterfeit protection of valuable documents.

6 cl, 1 dwg

Description

The invention relates to polymeric multilayer products, in particular to polymeric security elements used for visual verification of the authenticity of security printed products, such as securities, banknotes, passports and ID documents.

Various types of security elements are known for visual inspection. As a rule, such protective elements are based on the effects of changing the observed images recorded on the surface or inside these elements when changing the direction of observation.

For example, the use of multilayer interference and diffraction structures provides a change in the color and contrast of images when changing the directions of observation or illumination of the protective elements proposed in RU 2344047 C1, 01.20.2009. Changing the color and contrast of images is also achieved by using moire effects in protective elements with relief and spatially separated lattices (RU 2386544 C1, 04/20/2010). The effects of changing the observed images are widely known by using holographic solutions in the form of various types of Kinegram RU 2430836 C1, 10/10/2011, and solutions based on micro-raster lens structures WO 2007/133613 A2, 11/22/2007.

Protective elements are also known, made in the form of micro-sized relief surface structures in which two or more images are applied to different surfaces of micro-sized formations (RU 2395842 C2, 07.27.2010 and RU 2417897 C2, 05/10/2011). When considering such protective elements from different directions, various images will be observed formed on various collinear surfaces of micro-sized formations.

Protective elements are known that are formed by orienting magnetic pigments in the form of microparticles having the form of flat flakes (RU 2333105 C2, 09/10/2008). When forming an imprint, magnetic particles are affected by an inhomogeneous magnetic field. In this case, the particles are oriented in accordance with the direction of the magnetic field. Depending on the direction of observation, various color images will be observed in the light reflected by the magnetic particles.

The closest technical solution to the proposed one is the solution described in RU 2296677 C2, 04/10/2007, in which the images are formed as a result of the removal, by laser ablation, of the paint layer on the planes of micro-sized relief formations in the form of microprisms.

The above technical solutions are widely used in the manufacture of secure printing products, which increases the possibility of counterfeiting such elements and thereby reduces the efficiency of their use. In addition, the formation of such protective elements is carried out in the surface and near-surface layers, which leads to their weak copy protection and instability to external influences.

The task of the invention is to remedy the above disadvantages. The technical result is an increase in the degree of copy protection and resistance to external influences.

The technical result is achieved by the fact that the multilayer polymer protective element made in the form of a transparent or translucent paint layer deposited on a polymer substrate and having modified colorful areas obtained by laser exposure to the paint layer to form images detected by visual inspection in the paint layer made without relief, contains microparticles of magnetic materials with sizes from 1 μm to 100 μm, covered with layers of irreversible thermochromic materials Rials reactive with respect to laser radiation, or microvoids ranging in size from 1 to 100 microns, containing the above irrevocable thermochromic materials reactive with respect to laser radiation, and these microparticles or microvoids are regularly located and oriented. In this case, the images formed by the modified colorful areas are made by the action of laser radiation incident on the security element at various angles of at least α = arctg (h / d), where d is the average vertical size of lamellar particles or the average size of microvoids, μm, ah - the distance between the planes of the aligned particles or the average distance between microvoids, microns.

Microparticles of iron, chromium, or nickel oxides can be used as magnetic materials, and irreversible thermochromic materials, such as alloys of aluminum, copper, titanium, or special thermochromic irreversible dyes manufactured commercially, can be used as their coatings.

As materials with microvoids, film polymeric membranes with track pores, which are widely used in medicine as filters and produced by the domestic industry, can be used. The orientation of the micropores in the films can be perpendicular or at a given angle to the surface of the film, for example at an angle of 45 or 30 degrees. Moreover, the images formed by the modified colorful areas were made by the action of laser radiation incident on the security element at various angles of at least α = arctg (h / d), where d is the average vertical size of the plate particles, μm, ah is the distance between the planes aligned particles, microns.

It is additionally important that the microparticles are flat, in the form of plates, magnetic particles made, for example, of barium ferrite and iron borate and oriented by inhomogeneous magnetic fields with particle sizes of 10-100 microns in a plane and a thickness of 1-10 microns;

microparticles are needle-shaped magnetic particles, for example, chromium dioxide CrO ₂ or iron oxides Fe ₂ O _x with a length of 10-100 μm and a thickness of 1-10 μm, oriented by inhomogeneous magnetic fields;

microparticles are spherical particles made of glass, metal or ceramic with a size of 10-100 microns, such particles are used in the manufacture of retroreflective thin-film structures widely available on the market;

microvoids 1-10 microns in size, on the surfaces or in the volume of which thermochromic non-returnable materials are reactive with respect to laser radiation. Microvoids can be oriented cylindrical micropores, for example, in thin-film polymer track membranes.

In FIG. 1 shows the structure of the proposed security element.

As a specific example of the proposed technical solution, we consider a protective element (Fig. 1) containing a polymer substrate (made of polycarbonate, polypropylene, polyethylene terephthalate, etc.) 1 and a transparent lacquer layer 2 in which magnetic particles 3 are placed, for example, barium ferrite, or iron borate, flat plate shape with a magnetization M of 10 ⁴ -10 ⁶ A / m, covered with a colorful layer. The orientation and location of the magnetic particles 3 in parallel planes 4, perpendicular to the plane of the protective element, carry out inhomogeneous magnetic fields of 5 N of a magnitude of 10 ³ -10 ⁶ A / m Moreover, parallel planes with magnetic particles are located equidistantly at a distance from each other close to the average particle size. For particles with a size of 20 microns, the distance between the planes should be, respectively, 20 microns. Two different images are recorded in a protective element using laser radiation, under the influence of which irreversible changes in the color of the surface layer of particles occur. As a colorful coating of the surface of magnetic particles, metal and intermetallic thin-layer coatings, for example, based on aluminum, copper, cobalt and other metals with a characteristic gloss, can be used. Other industrially produced thermochromic non-return coatings can be used, for example, Dilor (www.deelor.ru), Double V (www.doublev.ru), BrizKolor (www.breezecolor.ru) and thermochromic paints of firms "Ultrachem Ltd." and T&K Toka Ltd. When recording the first image, the laser beam 6 is incident on magnetic particles on the right side of the parallel planes 4, at an angle equal to or greater than α = arctan (h / d), where d is the average vertical size of the plate particles, ah is the distance between the planes of the aligned particles.

The most optimal angle is 45 degrees when d = h. Recording is possible at other angles of incidence of the laser radiation, for example, in the range from 30 to 60 degrees, but the recording quality is in contrast, and the clarity of the images is deteriorated due to a part of the particle surface falling into the shadow from neighboring particles, or because of angles of incidence of laser radiation on the surface of the particles. The first image is formed on the right side of the particles by changing the color of the surface of the particles under the action of laser radiation in the areas determined by the configuration of the recorded image. The second image is formed on the left surfaces of the particles by a laser beam 7 incident on the aligned planes on the left side.

Another possible variant of the proposed protective element can be implemented in the form of a polymer track-pore membrane with microvoids in the form of micropores with a diameter of 1-3 microns, filled with the above laser-reactive materials. The orientation of the micropores can be perpendicular or inclined to the plane of the film membrane. The location and orientation of the micropores relative to each other determine the angles of incidence of the laser radiation used when recording images. The magnitude of these angles can be estimated by the formula α = arctan (h / d), where d is the average vertical size of lamellar particles or the average size of microvoids, μm, and h is the distance between the planes of aligned particles or the average distance between microvoids, μm.

Since magnetic particles and micropores are located inside transparent or translucent paint layers, external influences on them are much less than effects on relief pyramidal structures used in the technical solution chosen as an analogue. As a result, the service life of the protective elements is significantly increased. In addition, the proposed protective elements are much more difficult to copy and produce, since images are formed on the surfaces of particles inside the lacquer binder layers.

Claims (6)

1. A multilayer polymer security element for authenticating security of printed products, made in the form of a transparent or translucent ink layer deposited on a polymer substrate and having modified colorful areas obtained by the action of laser radiation on the ink layer to form an image detected by visual inspection, characterized in that the paint layer, made without relief, contains microparticles of magnetic materials with sizes from 1 μm to 100 m km, covered with layers of irreversible thermochromic materials reactive with respect to laser radiation, or microvoids with sizes from 1 μm to 100 μm, containing irrevocable thermochromic materials reactive with respect to laser radiation, moreover, said microparticles or microvoids are regularly located and oriented, and the images formed by the modified colorful areas are made by exposure to laser radiation incident on the security element at various angles of at least α = arc tg (h / d), where d is the average vertical size of lamellar particles or the average size of microvoids, μm, and h is the distance between the planes of the aligned particles or the average distance between microvoids, μm. 2. A multilayer polymer protective element according to claim 1, characterized in that the microparticles are flat, in the form of plates, particles oriented by inhomogeneous magnetic fields, with dimensions of 10-100 microns in a plane and a thickness of 1-10 microns. 3. The multilayer polymer protective element according to claim 1, characterized in that the microparticles are needle-shaped
particles with a length of 10-100 microns and a thickness of 1-10 microns, oriented by inhomogeneous magnetic fields. 4. A multilayer polymer protective element according to claim 1, characterized in that the microparticles are spherical particles with a size of 10-100 microns. 5. A multilayer polymer protective element according to claim 1, characterized in that the microvoids 1-10 microns in size are filled with materials reactive with respect to laser radiation. 6. A multilayer polymer protective element according to claim 5, characterized in that the microvoids are oriented cylindrical micropores, the inner surface of which is covered with layers of materials reactive with respect to laser radiation.

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