RU2687409C1 - Protective element - Google Patents

Abstract

FIELD: printing industry.SUBSTANCE: invention relates to protective elements used for authentication of printed products. Protective element contains a polymer substrate coated with a transparent or semitransparent UV-cured lacquer without a relief layer containing flat flake-like pigment microparticles with a surface-coloured layer. Size of flakes in plane is 10–100 mcm. Microparticles are arranged so that their coloured surfaces are collinear and form equal angles with the plane of the substrate over the entire surface or in specified non-overlapping regions. Microparticles in the lacquer layer do not overlap each other and are contained in a concentration which ensures transparency of the protective element at level of 50–70 %. Images are recorded in a protective element by laser radiation on a surface-coloured layer to form images detected during visual inspection.EFFECT: technical result consists in improvement of the image quality of the protective element and simplification of the process of authenticating the product containing the protective element.3 cl, 2 dwg

Description

The invention relates to the manufacture of layered products used for visual inspection of the authenticity of protected products, in particular printing products.

There are various types of protective elements for visual inspection. The most common protective elements, based on the effects of changing the type of observed images recorded on the surface or inside these elements, with a change in the direction of their observation.

For example, in security elements with multilayer interference and diffraction structures, when the angles of their observation or illumination change, the color and contrast of images change (RU 2344047, 2009).

The change in color and contrast of images is achieved using moire effects in elements with embossed and spatially separated grids (RU 2386544, 2010).

Protective elements are known, made in the form of embossed surface structures in which two or more images are applied to different surfaces of micro-dimensional formations (RU 2395842, 2010, RU 2417897, 2011).

When viewing such security features from different directions, different images are observed.

Protective elements are known which use magnetic pigments in the form of microparticles having the form of flat scales. When forming the impression, the magnetic particles are affected by a non-uniform magnetic field. The particles are oriented in accordance with the direction of the magnetic field. Depending on the direction of observation in the light reflected by magnetic particles, different color images are visible on the print (RU 2333105, 10.09.2008).

The above solutions are widely used in the manufacture of protected printing products. However, the formation of such protective elements, as a rule, is carried out in the surface and near-surface layers, which causes a weak protection of the product from copying and instability to external influences.

Protective pigments are known, which are characterized by well-visible and eye-catching optical properties, while they are able to produce a signal in the electromagnetic field that is intense enough to be detected. The pigment contains a transparent or translucent scaly electrically conducting core and a chromophore dielectric layer covering the core with a shell. The electrically conductive core has a transparent or translucent scaly substrate and a single or multilayer coating that covers the substrate with a shell or is on both sides of the substrate, and an outer conductive layer containing one or more doped metal oxides and having a thickness of at least 15 nm. The transparent or translucent flaky substrate is selected from the group consisting of layered aluminosilicates (mica), glass flakes, flaked SiO ₂ and flaky Al ₂ O ₃ (RU 2506294, 2014).

However, the well-known solution does not reveal how it is necessary to distribute and orient the known pigment particles in the security element.

The closest to the proposed solution is a multi-layer polymer protective element made in the form of a transparent or translucent paint layer deposited on a polymer substrate and having colorful sections modified by laser radiation. The color change of the paint layer occurs as a result of exposure to laser radiation and the formation of images detected by visual inspection as a result of exposure. The ink layer contains flat microparticles of magnetic materials with sizes of 1-100 microns, covered with layers of irretrievable thermochromic materials that are reactive with respect to laser radiation. These flat microparticles are regularly arranged and oriented so that their planes are parallel to each other and perpendicular to the substrate. The images formed by the modified paint areas are made by exposure to laser radiation falling on a protective element at various angles of a completely defined size (RU 2568708, 2015).

A disadvantage of the known element is the impossibility of recording and visualizing images differing from each other, formed on opposite external surfaces of the security element. In addition, the recording and visualization of images in a well-known solution requires the preliminary orientation of the microparticles in the element. Writing at large angles of incidence of focused laser beams and carrying out visualization of recorded images with observation directions that practically lie in the plane of the protective element, lead to a significant loss of contrast, brightness and clarity observed in the visualization of images.

The present invention is to eliminate the above disadvantages inherent in the prototype, and simplify the process of determining the authenticity of products containing a protective element.

The task is solved by the described protective element used to control the authenticity of printing products, which contains a polymer substrate, covered with a transparent or translucent UV-cured lacquer reliefless layer containing flat scaly pigment microparticles with a surface-colored layer, with a flake size in the 1-100 micron plane, arranged in such a way that their painted surfaces are collinear to each other and form with the plane of the substrate over the entire surface or in the specified I do not overlap the same angles, the microparticles in the lacquer do not overlap each other and are contained in a concentration that ensures the transparency of the protective element at a level of 50-70%, while the images are recorded in the protective element by the action of laser radiation on the surface-colored layer with the formation of images detected by visual control.

Preferably, the security element contains several recorded images, differing from each other in the orientation of the microparticles and visualized from one or both sides of the element at different viewing angles.

Preferably, the security element contains scaly microparticles capable of orientation in non-uniform magnetic or electric fields.

Options for the implementation of the proposed technical solutions are illustrated in figures 1 and 2, where:

1 - substrate;

2 - cured lacquer layer;

3 - painted surface of the pigment particle;

4 and 5 - directions of laser radiation;

6 - the direction of a non-uniform magnetic or electric field.

In the amount of the declared combination of features, the problem is solved. Confirmation of the achieved technical result when using the invention (without full disclosure of theoretical justifications) is explained below and is illustrated with examples that do not limit the scope of the invention.

The term: “transparency level” means the following.

In the absence of pigment particles in the layer, that is, at zero volume concentration of particles in the lacquer layer, the transparency of the protective element is determined by the transparency and thickness of the lacquer layer cured on its surface, and is assumed to be 100%. When pigment particles are introduced into the lacquer, the transparency of the security element decreases, and it depends on the transparency and size of the pigment particles, their concentration in the lacquer and the thickness of the cured lacquer layer.

Making a protective element of window type.

To obtain a protective element, transparent or translucent films of polypropylene or polyethylene terephthalate with thicknesses from 30 to 100 microns were used as a substrate.

In the process of applying a lacquer layer to a polymer substrate, due to surface tension forces, the pigment particles are oriented in such a way that their surfaces are parallel to the plane of the transparent substrate of the security element, as shown in FIG. one.

The images were recorded into the security element using both pulsed focused laser radiation and spatially modulated laser radiation, the directions of which are 4 and 5 in the figures. Irreversible changes in the color of the surface layer of pigment particles occur under the action of radiation.

Images were also recorded by ablation or discoloration of varnish on the surfaces of pigment particles.

It has been established that when pigment particles are exposed to the ink layer by pulsed optical radiation with sufficiently short durations of radiation pulses (less than 100 ns) and powers not exceeding certain threshold values (about 1-2 mW, at a wavelength of 1.06 μm) pigment particles and the composition of the used UV lacquer, the removal of the paint coat of the pigment particle is possible only from the side of the incident radiation. With longer durations of radiation pulses and high power levels, the removal of the paint layer occurs on both sides of the particles.

With correctly selected pulse durations, radiation power and wavelength, by scanning the radiation beam over the surface of a window-type protective element, it is possible to record an image observed only from the incident side of the recording radiation. Similarly, carry out the recording of another, different image on the second side of the protective element. In this case, each of the recorded images is visualized only from the side of the security element on which it was recorded.

Example number 1.

Previously it was found that the transparency of this protective element is 50-70% with the use of transparent UV lacquer, the thickness of the cured lacquer layer is 2-3 μm, when the concentration in the uncured lacquer of scaly pigment particles with a thickness of 1-2 μm is equal to 20-30 % vol.

A protective element was manufactured that contains a transparent polymer substrate (1), which is a transparent, non-photosensitive polycarbonate film with a thickness of 50 μm. The polymer substrate is coated with a transparent varnish UV-cured layer (2) from Sicpa company with a thickness of 2.5 μm. In the above-mentioned layer are placed flat pigment particles of a scaly form (3), containing an ink layer on the surface. Blue-green and violet-blue interference magnetic pigments with flakes thickness of 1-2 μm are used as pigment particles, the average size in the plane is 20-50 μm. The pigment particles in the layer do not overlap. The concentration of particles in the varnish is selected on the basis of ensuring the transparency level of the protective element of the window type, equal to 60%.

Example number 2.

Similarly to the protective element described in Example No. 1, a protective element was manufactured, which contains magnetic pigments from Merck golden (300th) and bronze (500th) series. Magnetic flaky particles of this pigment have a thickness of less than 1 micron, the average characteristic size in the plane of the particle is 50-100 microns. The surfaces of the particles are dyed with a silky golden-bronze color.

a) Transparency of a 50% protective element with a lacquer layer thickness of 3 μm was achieved at a pigment concentration in an uncured lacquer of the order of 20% by volume.

b) Transparency of a 70% protective element with a lacquer layer thickness of 5 μm was achieved at a pigment concentration in the uncured varnish of the order of 15% by volume.

The images were recorded in scanning modes by focused IR laser radiation with a wavelength of 1.06 μm and a power of 0.1-0.3 mW.

Example number 3.

The protective element is made similarly to those considered in examples 1 and 2. However, in this example, transparent pigments from Merck of the Miraval series based on potassium and aluminum borosilicate are used, which have flakes of 35-10 microns in size with flakes less than 1 micron thick. The transparency of the protective element at the level of 50% was achieved when the concentration of pigment particles in the uncured varnish was 10% by volume, and the transparency was equal to 70% when the concentration of the pigment particles in the uncured varnish was 5% by volume.

The images were recorded in scanning modes by pulsed laser focused radiation at a wavelength of 1.06 μm with an average power of 0.1–0.2 mW.

Example number 4.

Made protective elements containing pigment particles, like, used in examples 1 and 2.

In this case, the magnetic component is selected from the series: barium ferrite, iron borate, iron oxides, ferroelectric components.

Additionally, the pigment particles 3 were oriented in the paint layer of the security element by magnetic H or electric E fields in direction 6, as shown in FIG. 2. With the help of external magnetic or electric fields, in the given areas of the protective element, the particles are oriented parallel to each other at a given angle α to the surface of the transparent substrate. The orientation of the pigment particles in the protective element is fixed by the polymerization of lacquer by its UV exposure. In such areas it is also possible to record additional double-sided pairs of different images.

Metallic and intermetallic thin-layer coatings, in particular, based on aluminum, copper, cobalt and other metals with a characteristic luster, are used as a colorful coating for magnetic particles. In addition, you can use other special industrial thermochromic non-returnable coatings, for example, from companies: Dilor, Double V, BreezeColor, Ultrachem Ltd., and T & K Toka Ltd.

The advantages of the invention are as follows.

As can be seen from the above examples, the declared security element (window type), in contrast to the known one, provides the ability to record images differing from each other, which are observed through the light from opposite sides of the element.

Compared with the prior art, the process of recording and visualizing images is simplified, since it is carried out at smaller angles of incidence of the recording and reading radiations.

Since pigment flake particles are located inside the transparent or translucent paint-and-lacquer layers of the element, they have a slight external effect, which leads to an increase in the service life of the protective element. The proposed security element is difficult to copy and simulate, since the images are formed on the surfaces of the particles inside the lacquer layers.

Claims (3)

1. A security element used to control the authenticity of printed products containing a polymer substrate coated with a transparent or translucent UV-cured lacquer non-relief layer containing flat lamellar pigment microparticles with a surface-colored layer with the size of flakes in a plane of 10-100 microns, thus positioned that their painted surfaces are collinear to each other and form the same angles with the substrate plane over the entire surface or in given non-overlapping areas, microparticles in l kovom do not overlap each other and are contained at a concentration ensuring transparency of the security element at the level of 50-70%, wherein the image recording in the security element produced by the action of laser radiation on the surface to form a colored layer images detected by visual inspection. 2. The security element according to claim 1, characterized in that it contains several recorded images that differ from each other in the orientation of scaly microparticles that are visualized from one or both sides of the element at different viewing angles. 3. The security element according to claim 1, characterized in that it contains scaly microparticles capable of orientation in non-uniform magnetic or electric fields.

Images