RU2235021C2 - Data carrier with optically variable structure - Google Patents

Abstract

FIELD: technologies for protection from falsifications.

SUBSTANCE: device has optically variable structure with three-dimensional grid, which is placed in such a way relatively to cover, that, at different observation angles different optical effects appear, including variable ones. Three-dimensional grid and cover made in form of printed grid, are oriented one relatively to another in such a way, that rectilinear elements of printed grid are located at sharp angle, preferably from 0.3 to 10 degrees, to rectilinear elements of three-dimensional grid. Preferably, step between rectilinear elements of printed grid differs from step between similar rectilinear elements of three-dimensional grid and is not divisible relatively to it in cross-section which is perpendicular to rectilinear elements of three-dimensional grid. While observing data carrier at right and sharp angles an optical effect is observed in the surface in form of moire - smooth change of color, shade and color tinges, which is usable for determining origin of data carrier, but may not be reproduced by means of copying equipment at all or matching the original.

EFFECT: reliable protection of data carrier from falsification by simple means.

16 cl, 5 dwg, 6 ex

Description

The invention relates to information carriers with an optically variable structure characterizing the authenticity of an information carrier containing a coating made in the form of printed and three-dimensional rasters, which are thus oriented relative to each other, that at a right angle to the surface of the information carrier the coating is completely distinguishable, at an acute angle distinguishable in part. The primary area of use of the invention is the production of securities and currency.

To protect against counterfeiting, in particular, using color copiers or other copying methods, information carriers: banknotes, securities, credit cards, certificates, etc. provide optically variable security elements and holograms. At the same time, protection against falsification is based on the fact that a visually easy and clearly recognizable optically variable effect is not reproduced or is not reproduced sufficiently with the help of these copiers. A hologram information carrier is known, for example, from EP 440045 A2. This source proposes to apply the hologram as a prefabricated element or also as an embossment on the varnish layer applied to the information carrier. Along with the hologram, other optically variable structures can be added to the storage medium.

From RU 2161092 C2, a banknote is known which, in a partial region of its surface, is provided with a printed pattern of parallel lines. To create an optically variable effect, a three-dimensional linear structure (three-dimensional raster) is additionally applied to the information carrier in the region of this linear pattern by embossing. Due to the specific placement of the linear pattern and the three-dimensional raster, when viewed at a right angle to the surface of the information carrier, these lines are visible, and when viewed at an acute angle, the linear pattern is not visible.

Known from A.S. 1019012 A analogue is the closest to the invention in terms of the set of essential features - the prototype. It contains the following essential features that are common with the essential features of the invention: an information carrier with an optically variable structure characterizing its authenticity, contains a coating made in the form of a printed raster with straight-line elements located at the same distance from each other, and a three-dimensional raster located on equal distance from each other by rectilinear elements, which is so located with respect to the coating that at least partially the coating is located on a dimensional raster, and at the same time at a right angle to the surface of the information carrier, the coating is completely distinguishable, and at an acute angle - the part of the coating located on the surfaces of the three-dimensional raster, parallel to the observation direction or closed from the observer by the elements of the three-dimensional raster, is not distinguishable, but a part of the coating located on the surfaces of the three-dimensional raster facing the observer and not closed from the observer by the elements of the three-dimensional raster.

An optically variable structure is used as the so-called humane attribute, i.e. as a sign that a person can check without using auxiliary means, if necessary, along with other signs to determine the authenticity of the information carrier. Such signs are especially appropriate for banknotes and other securities, such as, for example, stocks, checks, etc. Cards that are currently used, for example, to identify a person or to complete transactions or provide services, can also be used as a storage medium.

The objective of the invention is to obtain a new effect in the form of moire - a smooth transition of colors. This problem is solved using the features of the claims.

The invention is based on such an implementation of an optically variable element of protection, which, with the simplicity of design and the simplicity of manufacturing technology, provides an effect that is observed quite definitely and explicitly, making it possible to determine without doubt the authenticity of an information carrier containing a coating.

This basic idea can be realized according to the invention in various ways, which mainly differ in the form of execution and the means used.

The basic idea implemented in various embodiments of the invention differs from the prior art in a number of advantages. For example, the protection of a document from counterfeiting is significantly enhanced by the manifestation of a moire effect — a moire color transition, namely a smooth color change or wave-like overflow of colors from one to another (moire color variable (MVC). Other advantages and improvements follow from the following description of embodiments, illustrated using the drawings, which schematically show:

figure 1 - information carrier according to the invention;

figure 2 is a cross section along the line aa of figure 1;

figure 3 is a cross section along the line bb In figure 1;

figure 4 is a view along arrow C of figure 3 (enlarged);

figure 5 is a cross section along the line aa of figure 1 (option according to paragraph 3 of the claims).

The storage medium 1 contains an optically variable structure 2 and a coating 3. In FIG. 1, an optically variable structure is located on a coating area, which is described by a white frame for clarity.

The design of an optically variable structure is a combination of a coating made in the form of a printed screen with rectilinear elements 4 and / or 5 located at the same distance from each other (elements 4 are located at the same distance from each other, elements 5 are located at the same distance from each other friend), and a three-dimensional raster 6 with rectilinear elements located at the same distance “a” from each other - tops (zeniths) 7 and troughs 8.

In the particular case, the three-dimensional raster 6 is an embossing made on the information carrier in the form of protrusions and / or recesses of a triangular shape in cross section located at the same distance from each other. The invention does not exclude the performance of a three-dimensional raster in cross section and of another shape, for example curved (wave-like) as in the prototype. Thus, the lateral surface of the protrusions and / or recesses can be made flat or in the form of a cylindrical surface. Peaks (zeniths) 7 and troughs 8 are rectilinear elements of a three-dimensional raster. Part of the coating or all of it is completely located on the surfaces of the three-dimensional raster.

A three-dimensional raster has the following preferred geometric parameters:

- the distance between the peaks (troughs) or step (size “a” in figure 2) is in the range from 30 to 100 microns;

- the distance between the peaks and troughs (size “in” in figure 2) is in the range from 50 to 100 microns,

- the angle (size “β” in figure 2) between the two faces 9 of the three-dimensional raster is in the range from 30 to 120 °.

A printed raster with rectilinear elements located at the same distance from each other has the following preferred geometric parameters:

- the width of the rectilinear element (stroke) (size “e” in figure 1) is in the range from 50 to 250 microns;

- the width of the gap (gap) between two rectilinear elements (size “E” in FIG. 3), if there is a gap between these elements, it is in the range from 50 to 250 microns.

The manufacturing process of an optically variable structure is the sequential manufacture of a coating and a three-dimensional raster.

The coating is made as follows. The surface of the information carrier is coated using known methods and means, for example by printing inks. The simplest coating design is a series of alternating lines (strokes) located with a gap (gap) equal to or slightly different from the width of the coating line (printed raster). The color of the coating can be any. Preferably, the color of the coating is contrasted with the color of the surface of the information carrier (substrate).

A three-dimensional raster is made after coating. To do this, you can use a tool (form, stamp), on the working surface of which the corresponding protrusions and depressions or corrugations are made. The geometric parameters of the protrusions and depressions of the tool are selected from the conditions for obtaining the specified geometric parameters of the three-dimensional raster.

The tool is oriented relative to the coating so that the rectilinear vertices of the protrusions of the tool are located at an acute angle α to the rectilinear elements of the coating. After that, the tool is pressed into the information carrier, forming a three-dimensional raster, which after removal of the tool takes a certain shape. The resulting shape of a three-dimensional raster may differ from the shape of the tool, which is associated with elastic deformations in the information carrier due to its physical and mechanical properties.

The result is a predetermined shape of the three-dimensional raster and its orientation relative to the coating, in which the rectilinear elements 5 and / or 6 of the printed raster of the coating are located at an acute angle α to the rectilinear elements 7 and / or 8 of the three-dimensional raster.

An optically variable structure made in accordance with the invention, depending on the structure of the coating and the embossed raster and their relative positioning, creates effects used to determine the authenticity of the information carrier.

Common to all structures according to the invention is that they and the effects they create cannot be copied using currently known reproduction techniques.

The optically variable structure 2 thus obtained, when viewed in the A1 direction, mainly perpendicular to the surface of the information carrier 1, is fully visible and perceived as a single-color field, and when viewed in the B1 and C1 directions at an acute angle to the surface of the information carrier 1, only those areas are visible which are open, i.e. when viewed at an acute angle, only part of the coating (information) is visible, visible at right angles. A coating located in areas of a three-dimensional raster that are not visible at the indicated acute angle is hidden from the observer by the elements of the three-dimensional raster and is not visible to him.

When sequentially viewed at right angles and at acute angles, alternating sections appear with a smooth moire color transition of the corresponding colors, from which the main visible image is obtained. When the position of the information carrier changes by 180 ° in the plane of its surface, the colored sections with the moire transition have a different form, i.e. carry other information.

Thus, the information, read at an acute angle to the surface of the information medium, allows both using the device and without it to determine the authenticity (originality) of the information medium (security, currency, etc.) and to distinguish it from a copy, since copies, even when viewed from an acute angle, all information visible at right angles to the storage medium will be visible.

In addition, a new effect is manifested in the fact that, as a result of the angular displacement of the printed and three-dimensional rasters, in comparison with the prototype, along the length of the protrusions and depressions of the three-dimensional raster, the coating is shifted relative to the surface of the three-dimensional raster in the transverse direction, which is clearly seen in FIG. 2 and 3. At the beginning of the three-dimensional raster (figure 2), a darker coating 4 is located only on the right sides of the three-dimensional raster. Toward the end of the three-dimensional raster (Fig. 3), the darker coating 4 is located not only on the right side of the three-dimensional raster, but also on top (at the zenith) and on the left side. Depending on the length of the three-dimensional raster and the angle of displacement, these displacements will be larger or smaller compared to FIG. Thus, the coating 4 gradually decreases in thickness in the visible part of the three-dimensional raster at an acute viewing angle. As can be seen from figure 3, there is a replacement of the specified coating or gap, or another coating that differs in color.

Depending on the value of the angle α, this substitution occurs faster or slower, ceteris paribus. When replacing one color with another, a smooth color change occurs, while the colors are mixed, and one color is replaced by another by forming an intermediate color, the color of which depends on which color is predominant. This effect is very similar to moire.

The most optimal from the point of view of the achieved result is the size of the angle α between the rectilinear elements of the three-dimensional raster and the rectilinear elements of the printed raster in the range from 0.3 to 10 °.

In order for the moire effect to be observed not only in the longitudinal direction with respect to the rectilinear elements of the three-dimensional raster, but also in the perpendicular direction, the invention proposes to choose the distance between the rectilinear elements of the printed raster from the condition that the cross-section step “a” between the same elements of the three-dimensional raster is different and is not a multiple of the step between the same elements of the printed raster located in the same section. This is clearly illustrated in figure 5. As a result of the inequality of these steps, the elements of the printed raster of one color are smoothly replaced by the elements of the printed raster of another color in the transverse direction relative to the rectilinear elements of the three-dimensional raster. Thus, the moire effect will manifest itself more expressively. In addition, it is much more difficult to achieve the exact combination of the elements of the printed and three-dimensional rasters, as is the case in the prototype, than to obtain the opposite result - the mismatch in step of the elements of the printed and three-dimensional rasters, as is the case in this invention.

If between the rectilinear elements of the printed raster to place other rectilinear elements of the printed raster, which differ from the first in color, then the moire effect is significantly enhanced. This embodiment of the invention is reflected in paragraph 4 of the claims, which also provides for the use of metameric elements of a printed raster. In this case, there may be a gap between the rectilinear elements of the printed raster, or it may not be. In the latter case, the rectilinear elements of the printing raster of one color and the rectilinear elements of the printing raster of another color are closely spaced.

Metameric elements of a printed raster are obtained using metameric inks in the visible range. These paints have very similar colors when illuminated by sunlight, and when illuminated by incandescent or fluorescent lamps, they acquire different shades. Paints that are similar in color and contain colorants that absorb energy differently in the short-wave infrared range also exhibit metamerism. When they are studied using an infrared optical converter, their infrared images differ significantly from each other.

These rectilinear elements of the printed raster can be made as two-color, and multi-color.

A number of patents for inventions have been issued for methods and means of protection using colorless images. Most of them consider printing inks and other compositions containing various phosphors, thermochromic and photochromic compounds.

марок

CD 320,

CD 304, Lumilux® Rot CD 303, Lumilux® Rot CD 118 и другие. Данные флуоресцирующие соединения возбуждаются в УФ-области в зоне от 200 до 400 нм.The authors of this invention used for coating paints containing organic and inorganic phosphors from the company

brands

CD 320,

CD 304, Lumilux® Rot CD 303, Lumilux® Rot CD 118 and others. These fluorescent compounds are excited in the UV region in the region from 200 to 400 nm.

When yttrium oxide activated with europium (Y ₂ O ₃ : Eu) was used in the coating, which is excited only by the action of X-rays and short-wave UV radiation in the region of 254 nm, bright red luminescence was observed. In the UV-radiation zone of 365 nm, luminescence is not observed.

When Ca phosphate activated by Ce (Ca ₃ (PO ₄ ) ₂ : Ce) and barium fluorosilicate activated by lead (BaFSiO ₃ : Pb) were used in the coating, excitation and radiation occurred in UV rays.

When using lanthanum (LaHal) activated halides in the coating, activated by rare earth elements, the excitation occurred in UV rays, and the radiation in IR rays.

When used in the coating of yttrium oxychlorides activated by ytterbium and erbium; Yttrium oxyhalagenides activated by ytterbium and erbium, excitation occurred in UV rays, and radiation in visible and UV rays (these substances are excited in the region from 950 to 1050 nm, emit in the region from 305 to 680 nm).

In addition to the above compounds, these properties are also possessed by oxyhelezonium-aluminum compounds of rare-earth elements. Their typical representatives are Y ₃ Fe ₄ Ni _0.5 Ge _0.5 O ₁₂ ; Y ₂ CaFe ₄ SiO ₄ ; Y ₃ Fe ₃ Al ₂ O ₁₂ ; YCa ₂ Fe ₄ VO ₁₂ .

The use of thermochromic printing inks to protect securities and documents is characterized by the use of both relatively cheap and relatively expensive thermochromic substances.

When used in the coating composition based on cobalt salts (CoC1 ₃ × 6H ₂ O, Co ₂ (SO ₄ ) ₃ × 6H ₂ O), which is applied to the surface of the paper using a size press as a surface sizing, the surface of the paper was pink, characteristic of cobalt water salts. When heated in the temperature range from 30 to 100 ° C and after evaporation of water, the surface of the paper becomes colorless. In a room with medium humidity, the surface of the paper again turns pink. This process can be repeated many times.

The authors used coatings based on liquid crystals - cholesterol compounds in microcapsules with an antioxidant in a ratio of 1: 1 or 2: 1 are mixed with acrylic latex and applied to the surface of the paper. The need to use microcapsules is caused by the low chemical resistance of cholesterol derivatives with respect to oxygen. Hydroquinone and other compounds are used as antioxidants. Coatings on paper changed color when heated from 30 to 80 ° C.

These chemical compounds are used by introducing into the paper pulp or applying to its surface.

When using coatings made of photochromic paints, in particular, based on spiropyrans and spirooxazines, which have the ability to be invisible to the eye, when irradiated with ultraviolet light in the wavelength range from 200 to 400 nm for several seconds, they acquired color. About 30 seconds after turning off the ultraviolet source, the colors returned to their original colors.

The return to the original color was accelerated by slight warming. This cycle has been repeated many times.

The authors also use coatings containing special substances that absorb ultraviolet radiation only in the wet state. This property of these substances is reversible. As these substances were used NRT - hexamethylphosphatiamine; DNRV - 2,4 dihydroxybenzophenone; OPS - octophenyl salicylate; RMB - monobenzoate resenate; UVG-2-hydroxy-4-methoxybenzophenone, AT-539-2-ethylhexyl-2-cyano-3,3'-diphenylacrylate.

For applying to manufactured paper using 10% solutions in organic solvents with a small amount of a binder or using flexographic methods.

When performing a three-dimensional raster in the form of faces, the angles between adjacent faces are the same on one face value of a security or currency and different on different face values of a security or currency. Preferably, the angles between the faces of the three-dimensional raster are in the range of 30 to 120 °.

This embodiment allows the use of control equipment that reads information at various angles to the surface of the information medium to simultaneously determine the authenticity and denomination, regardless of which denomination is depicted on a security or currency.

Example 1

Obtaining a protective visible image, when exposed to visible and ultraviolet radiation, an optically variable structure appears, containing hidden information in the form of additional visual effects with a smooth moire-like color transition.

To create this image, two printing inks are used: one blue, containing the Phthalocyanine blue pigment and Orlum red 616 RT, and the other red, containing Lacquer pigment Red ZhB and Orlum yellow-green 520 RT.

To create an optically variable effect, the following technical parameters of the main polygraphic image (printed raster) and three-dimensional relief raster (stamping) are used:

- the angle between the rectilinear elements of the three-dimensional raster and the rectilinear elements of the printed raster is 1.5 °;

- the main printing image (coating in the form of a printed raster): the width of the stroke of the seal is 150 microns, the gap width is 150 microns, the pitch of one image component is 600 microns;

- three-dimensional embossing (three-dimensional raster): the width of the stroke is 40 microns, the depth of the shape for embossing is 69 microns, the step of the engraving of the engraving is 600 microns, the angle in the recesses of the shape for embossing is 45 °.

After obtaining an optically variable structure using a three-dimensional raster when exposed to visible radiation and viewing at an angle of 45 °, hidden information with additional visual effects appears, with a smooth moire-like transition of colors from blue to red.

When exposed to ultraviolet radiation and viewed at an angle of 45 °, the appearance of hidden information with additional visual effects, with a smooth moire-like transition of fluorescence colors from red to yellow, is observed.

Example 2

Obtaining a protective visible image, when exposed to visible and ultraviolet radiation, visible information and structure appears, containing hidden information in the form of additional visual effects with a smooth moire-like color transition, and when irradiated in the ultraviolet and near infrared, a similar optically variable structure appears containing hidden information in the form of additional visual effects with a smooth moire-like transition of a different color. When exposed to this image of near infrared radiation, its infrared image changes.

Two brown printing inks are used to create the image (coating): one containing Pigment yellow transparent O, Lacquer pigment ruby SK, Pigment blue phthalocyanine and Orlum yellow 560 RT, very weakly absorbs near infrared radiation, and the other containing Lacquer pigment Red ZhB, Soot and Orlum red 616 RT, absorbs near infrared radiation. The relations between the components of the paints are selected in such a way that when illuminated by sunlight, they are very close in color.

To create an optically variable effect, the following technical parameters of the main printing image and three-dimensional embossing are used:

- the angle between the rectilinear elements of the three-dimensional raster and the rectilinear elements of the printed raster is 0.3 °;

- the main printing image (coating in the form of a printed raster): the width of the stroke of the seal is 150 microns, the gap width is 150 microns, the pitch of one image component is 500 microns;

- three-dimensional embossing (three-dimensional raster): the width of the stroke is 40 microns, the depth of the shape for embossing is 65 microns, the step of the engraving of the engraving is 600 microns, the angle in the recesses of the shape for embossing is 45 °.

After obtaining an optically variable structure when exposed to incandescent light and viewing at an angle of 45 °, hidden information with additional visual effects appears, with a smooth moire-like transition of colors from red-brown to purplish-brown. In this case, the metamer effect is enhanced.

When exposed to ultraviolet radiation and viewed at an angle of 45 °, the appearance of hidden information with additional visual effects, with a smooth moire-like transition of fluorescence colors from yellow to red, is observed.

When observing an image at an angle of 45 ° in the infrared optical converter, its infrared image changes. The areas of the image that absorb near infrared radiation disappear and merge with the areas of the image that do not absorb near infrared radiation.

Example 3

Obtaining a protective invisible image, when exposed to ultraviolet radiation, visible information appears, additionally containing a hidden optically variable structure.

To create this image, two colorless printing inks are used: one containing Orlum yellow 560 RT, and the other - Orlum red 616 RT.

To create an optically variable effect, the following technical parameters of the main printing image and three-dimensional embossing are used:

- the angle between the rectilinear elements of the three-dimensional raster and the rectilinear elements of the printed raster is 10 °;

- the main printing image (coating in the form of a printed raster): the width of the stroke of the seal is 100 microns, the gap width is 100 microns, the pitch of one image component is 600 microns;

- three-dimensional embossing (three-dimensional raster): the width of the stroke is 50 μm, the depth of the shape for embossing is 69 μm, the step of the engraving of the engraving is 600 μm, the angle in the recesses of the shape for embossing is 45 °.

After obtaining an optically variable structure under the influence of ultraviolet radiation (in the range from 200 to 400 nm) and viewing at an angle of 45 °, the appearance of hidden information with additional visual effects, with a smooth moire-like transition of fluorescence colors from yellow to red, is observed.

Example 4

Obtaining a protective invisible image, when exposed to ultraviolet radiation, visible information appears, additionally containing a hidden optically variable structure.

To create this image, two colorless printing inks are used: one containing Orlyum yellow 560 RT and phosphor K - 77, and the other - Orlyum red 616 RT and phosphor L - 35.

To create an optically variable effect, the following technical parameters of the main printing image and three-dimensional embossing are used:

- the angle between the rectilinear elements of the three-dimensional raster and the rectilinear elements of the printed raster is 2.5 °;

- the main printing image (coating in the form of a printed raster): the width of the stroke of the seal is 150 microns, the gap width is 150 microns, the pitch of one image component is 800 microns;

- three-dimensional embossing (three-dimensional raster): the width of the stroke is 40 microns, the depth of the shape for embossing is 69 microns, the step of the engraving of the engraving is 600 microns, the angle in the recesses of the shape for embossing is 45 °.

After obtaining an optically variable structure under the influence of long-wave ultraviolet radiation ( _λmax = 365 nm) and viewing at an angle of 45 °, hidden information with additional visual effects appears, with a smooth moire-like transition of yellow to red fluorescence colors.

When exposed to short-wave ultraviolet radiation ( _λmax = 254 nm) and viewed at an angle of 45 °, hidden information with additional visual effects appears, with a smooth moire-like transition of fluorescence colors from orange to pale purple.

Example 5

Obtaining a protective invisible image, when exposed to ultraviolet radiation, visible information appears, additionally containing a hidden optically variable structure.

To create this image, two colorless printing inks are used: one containing Orlum yellow 560 RT and the photochromic spirooxazone compound VA-231, and the other - Orlum red 616 RT and the photochromic spirooxazone compound VA-232.

To create an optically variable effect, the following technical parameters of the main printing image and three-dimensional embossing are used:

- the angle between the rectilinear elements of the three-dimensional raster and the rectilinear elements of the printed raster is 3.5 °;

- the main printing image (coating in the form of a printed raster): the width of the stroke of the seal is 150 microns, the gap width is 150 microns, the pitch of one image component is 600 microns;

- three-dimensional embossing (three-dimensional raster): the width of the stroke is 40 microns, the depth of the shape for embossing is 79 microns, the step of the engraving of the engraving is 600 microns, the angle in the recesses of the shape for embossing is 45 °.

After receiving an optically variable structure and after exposure to ultraviolet radiation (in the range from 200 to 400 nm) for 1.5 minutes when illuminated with visible light, when viewed at an angle of 45 °, hidden information with especially characteristic effects and a smooth moire-like color transition from red to blue. Directly under the influence of ultraviolet radiation (in the range from 200 to 400 nm), when viewed at an angle of 45 °, the appearance of hidden information with especially characteristic or additional visual effects and a smooth moire-like transition of colors from yellow to red is observed.

Example 6

Obtaining a protective invisible image, when exposed to ultraviolet radiation and thermal exposure, visible information appears, additionally containing a hidden optically variable structure.

To create this image, a colorless printing ink containing a thermochromic compound with a gray color transition and Orlum yellow 560 RT is used, as well as a colorless printing ink containing a thermochromic compound with a blue color transition and Orlum red 616 RT.

To create an optically variable effect, the following technical parameters of the main printing image and three-dimensional embossing are used:

- the angle between the rectilinear elements of the three-dimensional raster and the rectilinear elements of the printed raster is 1.5 °;

- the main printing image (coating in the form of a printed raster): the width of the stroke of the seal is 100 microns, the gap width is 100 microns, the pitch of one image component is 600 microns;

- three-dimensional embossing (three-dimensional raster): the width of the stroke is 40 microns, the depth of the shape for embossing is 69 microns, the step of the engraving of the engraving is 600 microns, the angle in the recesses of the shape for embossing is 45 °.

After obtaining an optically variable structure when exposed to heat up to 100 ° C, a visible image appears in gray-blue color, additionally containing a hidden optically variable structure, in which, when viewed at an angle of 45 °, hidden information appears with especially characteristic or additional visual effects and a smooth moire-like transition gray or blue colors; such hidden information with particularly characteristic or additional visual effects, with a smooth moire-like color transition, but already fluorescing with yellow or red light against a common orange background at the same viewing angle, appears when the image is illuminated with ultraviolet radiation.

Claims (16)

1. A data carrier with an optically variable structure characterizing its authenticity, comprising a coating made in the form of a printed screen with rectilinear elements located at the same distance from each other, and a three-dimensional raster with rectilinear elements located at the same distance from each other, which is so located along with respect to the coating, that at least partially the coating is located on a three-dimensional raster, and at the same time at a right angle to the surface of the information carrier, the coating is completely decomposed supposedly, and at an acute angle, the part of the coating located on the surfaces of the three-dimensional raster located parallel to the direction of observation or closed from the observer by the elements of the three-dimensional raster is not distinguishable, but the part of the coating located on the surfaces of the three-dimensional raster facing the observer and not closed from the observer is distinguishable elements of a three-dimensional raster, while the rectilinear elements of the three-dimensional raster are located at an acute angle to the rectilinear elements of the printed raster, characterized in that the distance between ryamolineynymi printed raster elements is chosen from the condition that the cross-sectional step between the same three-dimensional raster elements is different and not a multiple of the step between the same printed raster elements located in the same section. 2. The storage medium according to claim 1, characterized in that the angle between the rectilinear elements of the three-dimensional raster and the rectilinear elements of the printed raster is in the range from 0.3 to 10 °. 3. The storage medium according to one of claims 1 and 2, characterized in that the rectilinear elements of the printed raster have a different color and / or are metameric. 4. The storage medium according to claim 3, characterized in that between the rectilinear elements of the printed raster of the same color are rectilinear transparent elements of the printed raster. 5. The storage medium according to claim 3, characterized in that the rectilinear elements of the printed raster of one color and the rectilinear elements of the printed raster of another color are adjacent. 6. The storage medium according to one of paragraphs.3 and 5, characterized in that the rectilinear elements of the printed raster are made in two colors. 7. The storage medium according to one of claims 1 to 6, characterized in that at least some rectilinear elements of the printed raster contain thermochromic compounds activated by heating in the temperature range from 30 to 100 ° C. 8. The information carrier according to one of claims 1 to 6, characterized in that at least some rectilinear elements of the printed raster contain photochromic compounds activated by ultraviolet light in the wavelength range from 200 to 400 nm. 9. The storage medium according to one of claims 1 to 6, characterized in that at least some rectilinear elements of the printed raster contain phosphors activated when illuminated with ultraviolet optical radiation. 10. The storage medium according to claim 9, characterized in that the elements of the printed raster containing phosphors activated by ultraviolet optical radiation, have luminescence in the wavelength range from 400 to 700 nm. 11. The storage medium according to one of claims 1 to 6, characterized in that at least some rectilinear elements of the printed raster contain phosphors activated when illuminated by visible optical radiation. 12. The storage medium according to claim 11, characterized in that the elements of the printed raster containing phosphors activated by visible optical radiation have luminescence in the wavelength range from 700 to 1100 nm. 13. The storage medium according to one of claims 1 to 6, characterized in that at least some rectilinear elements of the printed raster contain phosphors activated when illuminated by infrared optical radiation. 14. The storage medium according to item 13, characterized in that the elements of the printed raster containing phosphors activated by infrared optical radiation, have luminescence in the wavelength range from 400 to 700 nm. 15. The information carrier according to one of claims 1 to 14, characterized in that the surfaces of the three-dimensional raster are made in the form of faces, while the angles between adjacent faces are the same on one face value of a security or currency and different on different face values of a security or currency. 16. The storage medium according to clause 15, wherein the angles between the faces of the three-dimensional raster are in the range from 30 to 120 °.

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