RU2463169C2 - Safety element with several structures having optically variable parameters - Google Patents

Abstract

FIELD: printing.

SUBSTANCE: application describes a safety element with a structure having optically variable parameters, formed with printed structure. The first printed structure consists of the first printed elements and is combined with coating contrasting with the surface of the safety element so that at least some parts of the coating can be seen by looking at the safety element at an angle lying in the first range of angles of view, but at least partially hidden at viewing it at an angle within the second range of angles of view. When tilting the safety element to and fro about the first axis, the first tilt-effect is observed. The structure having optically variable parameters is formed with at least one-half printed structure, which is located within the first printed structure and creates in addition to the first tilt-effect the second tilt-effect and which is integrated in the first printed elements through partial change of their geometry or consists of second printed elements, each of which abuts at a certain angle to the side surface of the first printed elements.

EFFECT: proposed safety element provides increased protection against counterfeiting.

31 cl, 26 dwg

Description

The present invention relates to a security element with an optically variable structure formed by an embossed structure. Such an embossed structure is combined with a coating contrasting with the surface of the protective element in such a way that at least individual sections of the coating are visible when viewing the protective element at an angle lying in the first range of viewing angles, but are not visible when viewing it at an angle lying in the second range of angles view. When the protective element is tilted in one or the other direction around the corresponding axis and, therefore, when viewed alternately at viewing angles lying in the first and second ranges of viewing angles, a kipp effect is observed in which at both different angles of view, respectively, when light is incident at different different colors are visible at the corners or different levels of brightness are visually perceived.

In this regard, for example, from WO 97/17211, there is known a storage medium provided with an element with optically variable properties formed by an embossed structure and a coating in the form of a print (printed image) or linear raster. The embossed structure or coating is modified by partially changing it, respectively, by partially changing its structure in such a way as to enhance the already known optically variable effect or to create at least one more visually perceptible effect. Such an element with optically variable properties is distinguishable visually, but due to its optically variable properties it cannot be reproduced on photocopiers. Copying devices are able to reproduce the original to be copied from only one direction of light incidence on it, because of which there is no optically variable effect on the copy, i.e. the possibility of visual perception of different information is lost when viewing a copy from different directions. Thus, a known element with optically variable properties can be used to protect against copying.

From WO 02/20280 A1, a structure having optically variable properties is known which is formed by a coating and an embossed structure superimposed on it. The entire area occupied by the coating and embossing is subdivided into smaller separate sections, on each of which either the coating or the embossing is uniform in the entire area occupied by this separate section, but different from the adjacent separate sections. The other part of the structure possessing optically variable properties (i.e., embossing, respectively coating) has an unchanged performance in all these separate sections, i.e. the arrangement of the elements of this part, which has optically variable properties of the structure in all individual sections, is subject to invariable laws. Different embossed substructures according to WO 02/20280 A1 are, for example, embossed substructures that are located at adjacent separate sections with a phase shift relative to each other, have different raster lineatures or have different orientations, i.e. embossed substructures located in adjacent separate sections are oriented at a certain angle to each other. In addition, the embossed substructures in adjacent individual sections can also be displaced relative to each other. In this case, the orientation or orientation of such embossed substructures remains unchanged.

The present invention was based on the task of improving the known security elements and, above all, increasing the degree of protection provided by them against counterfeiting.

This problem is solved using the distinguishing features of the independent claims. Various preferred embodiments of the invention are presented in the dependent claims.

The objects of the invention in this case are a protective element, a storage medium with a protective element, as well as an embossing tool for the manufacture of a protective element. A data carrier in this context primarily means a valuable document, such as, for example, a banknote, security, credit card, debit card, identification card, passport, certificate and other similar document, as well as a label, packaging or other element to protect various goods and products from counterfeiting.

According to the invention, the structure having optically variable properties is also formed by at least one second embossed structure, which is located within the first embossed structure and creates, in addition to the first kipp effect, a second kipp effect. In a preferred embodiment, the second kipp effect is observed when examining the protective element either within the first or second range of angles of view in which the first kipp effect is observed, or when moving from the first to the second or from the second to the first range of angles of view in which the first kipp effect is observed.

In a first alternative embodiment, i.e. in the embodiment in which the second kipp effect is observed when viewing the security element within the first or second range of viewing angles, the second embossed structure is superimposed on the first embossed structure so that it is visible when viewing the security element within the first or second range of viewing angles and almost or completely not visible when viewing the protective element within a correspondingly different range of viewing angles. Thus, when considering the security element according to the invention, at an angle lying in the range of viewing angles at which the second embossed structure is almost or completely invisible, only the first embossed structure can be seen. When viewing the protective element at an angle lying in a different range of viewing angles, the second embossed structure is additionally visible, and when the protective element is tilted or rotated around a second axis other than the first axis, the second kipp effect is observed.

In a particularly preferred embodiment, at least one second embossed structure consists of second embossed elements, each of which is adjacent at a certain angle to the side surface of the first embossed elements. In accordance with this, the second embossed elements, like short spikes or attachments, protrude at a certain angle from the side surface of the first embossed elements and create a second kip effect on this side of the first embossed elements. The angle at which the second embossed elements are adjacent to the side surface of the first embossed elements corresponds to the angle between the first axis, when the protective element is tilted around which the first kip effect is observed, and the second axis, when the second element is tilted around which the second kip effect is observed .

The first and second embossed structures are preferably made in the form of raster structures, most preferably in the form of a linear raster with a constant lineature, especially with a triangular, trapezoidal, sinusoidal or semicircular cross-sectional profile, and preferably made on the basis of a protective element in the form three-dimensional linear, wavy or other similar structures, for example, relief structures. The second embossed structure does not have to have the same profile in cross section as the first embossed structure. So, for example, the first embossed structures can have a triangular profile in cross section, and the second embossed elements can have a semicircular profile.

In a second alternative embodiment, i.e. in the embodiment in which the second kipp effect is observed when examining the security element when switching from the first to the second or from the second to the first range of viewing angles, at least one second embossed structure is integrated into the first embossed elements by partially changing their geometry. To this end, in a preferred embodiment, the first embossed elements are modulated in height in their longitudinal or transverse direction, in width or in inclination of their side surfaces, while modulation of the width and / or inclination of the side surfaces can take place on one or both sides of the embossed element. When the security element is tilted around the first axis, in areas where the second embossed structure is located, in addition to the first kipp effect, a second kipp effect is observed.

The first embossed elements may, for example, have two wedge-shaped converging side surfaces of different colors, and the second embossed structure can be in this case in the form of a groove-shaped depression on the top of the wedge in its longitudinal direction. The lateral surfaces of the cavity, in turn, have a color contrasting with the color of the adjacent side surface of the first embossed elements. As a result, when the security element is tilted around the first axis, the first side surface of the first embossed element is first visible, and at the end of the first range of angles of view, the first side surface of the depression is seen parallel or almost parallel to the first side surface of the first embossed element. With a further inclination of the security element around the first axis, the second side surfaces of the first embossed element and the depression also enter the field of view, remaining visible until, finally, the first side surface of the first embossed element and then the second side surface of the cavity are closed by the second side surface of the first embossed element. In the same areas with optically variable properties of the structure in which there is no second embossed structure, when the protective element is tilted to one or the other side around the first axis, only both side surfaces of the first embossed structure are alternately visible, i.e. only the first kipp effect is observed.

In a preferred embodiment, the first and second embossed structures are in the form of blind embossing. Similar embossed structures in the form of blind embossing are obtained by printing using a steel gravure printing form, the so-called steel engraving. In the printing process, the paper is pressed into the recesses on the areas of the printing form intended for blind embossing and thereby is irreversibly deformed. In contrast to the areas of the printing form intended for obtaining an impression, its areas intended for blind embossing do not fill with paint, and therefore the base material of the document protected from forgery is only irreversibly deformed, i.e. is embossed in these areas. When examining embossed structures obtained by blind embossing, special three-dimensional optical impressions are created due to chiaroscuro effects. In addition, embossed structures obtained by blind embossing due to their relief at appropriate sizes are also easily distinguishable by touch.

When embossed elements of the first or second embossed structures of different heights are made, blind embossing is also called halftone blind embossing.

Blind embossing can also be done with thermo methods. In this case, the plastic or polymer base is thermally deformed by the action of heat, which allows to obtain smaller structures than when embossing a paper base. This method is used primarily for the embossing of plastic, respectively polymer banknotes or bank cards, debit cards, credit cards, SIM cards, customer cards (discount cards) or similar plastic cards.

In another preferred embodiment, the first and second embossed structures are in the form of colorful embossing. In this case, the optically variable effect created by the protective element is retained, although colorful embossing is used instead of the blind. The aforesaid means that a structure with optically variable properties in at least some of its sections has a second coating that also contrasts with the surface of the information carrier, which is combined with embossed elevations of the embossed structure. The advantage of having a second coating is to stabilize the embossed structure without an additional printing process. In addition, the advantage of such a protective element is the ability to integrate it into the plot of the image printed by metallographic printing, and thereby in the color and subject design of the surrounding plot.

In case of colorful embossing, the indentations of the printing plate engraved in the form of lines are filled with paint. Excess ink is removed from the printing form with an eraser roller or squeegee, leaving the recesses engraved as lines to the edges filled with ink. Then, during the printing process, the sealed storage medium, typically high-pressure paper, is pressed by a pressure cylinder with an elastic surface to the printing form. The information carrier is then pressed into the indentations of the printing plate engraved in the form of lines in the form of lines and in this way is in contact with the printing ink. When separating the storage medium from the printing form, it draws the printing ink from the recesses of the printing form engraved in the form of lines. The impression obtained in this way consists of printing lines, the thickness of the ink layer forming which varies depending on the depth of the engraved recesses of the printing form. In this case, the information carrier is so pressed into the recesses of the printing plate that it not only captures or perceives the ink from the recesses, but is also embossed, acquiring a relief structure.

In one particularly preferred embodiment, the embossed structures are formed by linear (line-shaped) embossed elements, which in the preferred embodiment have a rectilinear shape, but may also have a wavy and / or curved shape. A linear embossed element is obtained by a channel-shaped recess on the working surface of the embossing stamp, respectively, of the embossing cylinder. Such a recess has such a profile that during embossing embossed elements are formed with at least two side surfaces facing in opposite directions, each of which is visible mainly from only one of the different directions. So, for example, when making a recess with a triangular profile, two side surfaces are formed, which are simultaneously visible when viewing the protective element from a right angle. When examining the protective element at an acute angle, only one side surface is visible, since the other side surface is closed by the opposite, visible side surface. Thus, when alternately viewing the protective element at direct and acute angles of view, a kipp effect is observed.

Typically, the lines of the linear raster structure forming the coating and the linear embossed elements are oriented parallel to each other, and therefore, lines of the same color are located on one side surfaces of the embossed elements of the embossed structure, and lines of a different color are located on other side surfaces. Accordingly, when examining a structure with optically variable properties from an acute angle of view, one of two colors is visible depending on the viewing direction, and when examining a structure with optically variable properties from a right angle, both colors are visible. As a result, the coating and the embossed structure in interaction with each other create a kipp effect with a change of colors (color kipp effect).

In another preferred embodiment, the embossed structures are formed by non-linear embossed elements, known primarily from WO 2006/018232 A1. Non-linear embossed elements have flat and / or curved side surfaces, primarily in the form of n-coal pyramids, tetrahedrons, truncated pyramids, cylindrical segments, cones, truncated cones, paraboloids, polyhedra, rectangular parallelepipeds, prisms, spherical sectors, spherical segments, spherical layers, hemispheres, barrels or tori. Non-linear embossed elements can also be made in the form of a so-called divided torus, which is divided parallel to the plane in which its large radius lies. It is most preferable to use embossed elements in the form of spherical segments or triangular or quadrangular pyramids. The advantage of nonlinear embossed elements also lies in the possibility of simple integration into a structure with optically variable properties in addition to the first and second information of the third, fourth, etc. information, and each information can be seen only when viewing the protective element from a certain direction and at a certain angle of view, since non-linear embossed elements have several side surfaces on which different information or parts of it can be purposefully and separately separated.

The first and / or second embossed structures and / or the contrast coating reproduce at least one information that is transmitted by the contours of the embossed or printed sections. Such information is in the form of a graphic and / or alphanumeric image and is, for example, a number, a letter, a portrait image, an animal image, a plant image, a landscape image or a building image.

The height and / or lateral size of the embossed structures due to the roughness of the emission paper should primarily be more than 30 microns.

In a particularly preferred embodiment, at least one second embossed structure is subdivided into separate sections and reproduces additional information. Depending on the design, it can, among other things, hide, highlight, matt or shade certain areas. With the same arrangement, it contributes to a clear visual perception of information, and with a narrowing or disharmonious arrangement, it can enhance the kipp effect.

The coating is preferably in the form of a flat single or multi-color print. A multi-color print in the most preferred embodiment is a printed pattern of lines that can be directly adjacent to each other or can be spaced from each other. In the first case, a pattern of lines covering its entire area is applied to the information carrier, preferably in the form of an alternating sequence of three lines of cyan, magenta, and yellow primary colors. When the lines are indented from each other, it is preferable that one of the lines of the pattern formed by them be formed by the color of the base of the information carrier. Both of these features can also be used in combination with each other. So, for example, when printing on a magenta-colored basis of an alternating sequence of two adjacent blue and yellow lines with an interval between each pair of lines, the basis of the information carrier forms an “missing” third line of such a sequence.

Typically, lines of individual colors are sequentially printed based on a storage medium. Moreover, for the first run, all lines of the first color are printed first, for the second run all lines of the second color are printed, for the third run all lines of the third color are printed, etc. For each color, they use their own printing plate or their own printing cylinder, on which / which paint of the corresponding color is applied and then the basis of the information carrier is sealed with it.

In principle, inks of all colors can be printed on the basis of the information carrier and in one run. In this case, inks of individual colors are sequentially or simultaneously applied to one single printing plate or to one single printing cylinder and then they seal the base of the information carrier.

The coating can be applied by conventional printing methods, i.e. primarily by flat printing, such as offset printing, gravure printing, such as printing or flexographic printing, screen printing, gravure printing, such as autotypic intaglio or metallographic printing, or thermographic printing, such as, for example, the thermal transfer method.

For printing coating, it is preferable to use fully opaque printing inks. It is particularly preferable to use printing inks with high transmittance, i.e. printing inks based on translucent varnishes with a certain content of colored pigments in them. Similarly, transparent lacquers can be used, to which machine-readable features are added, such as, for example, luminescent substances, electrically conductive particles, or substances that absorb infrared or x-ray radiation. Such a coating with machine-readable features contrasts with the surface of the security element, since it does not contain machine-readable features. Obviously, machine-readable features may also be components of translucent or opaque inks.

The lines forming the coating are preferably in the form of straight lines and it is most preferable to arrange them parallel to each other. The lines can also be made in the form of concentric circles or confocal ellipses or oval, wavy or any other shape. In addition to this, several such various line designs can also be used in combination with each other.

At least one second embossed structure may also be combined with a second coating contrasting with the surface of the information carrier. In this case, the first coating is applied to the first embossed structure, and the second coating to the second embossed structure. As a result, when examining the second embossed structure, additional information is visible that is located within the coating with which the first embossed structure is combined.

The coating is consistent with the first and second embossed structures. So, for example, it is possible to purposefully highlight, enhance, weaken or alter colors or patterns when viewing a security element from an acute angle of view, and thereby reproduce another additional information. When viewed from a right angle or from the side of the opposite side surface, such additional information remains hidden.

The coating and embossed structures are preferably placed at the same spatial frequency, i.e. in the form of a raster with the same line for embossed structures and coating. However, the coating and embossed structures can also be placed only with similar spatial frequencies to create a haze or moire effect, or with completely unrelated spatial frequencies. In this way, you can create other optical effects, which can only be seen when viewing the protective element at different angles or when light is incident at different angles.

Both stages — embossing and printing — for the manufacture of an optically variable structure can be performed in any order. Thus, in particular, on the basis of the information carrier, it is possible to first emboss the structure, and then by printing, apply the coating on the basis of the information medium, or, conversely, first, by printing, apply the coating on the basis of the information medium, and then perform the embossed structure on the basis of the information medium. Both stages considered can be performed simultaneously, combining them into one stage.

The information placed on the security element by embossing and coating it may be, for example, letters and / or numbers, as well as any symbols, graphic elements, graphs, images, one- or two-dimensional codes or other patterns and patterns.

The security element may have a single or multi-layer base that can be coated, sealed, glued, laminated, laminated in one or more layers or otherwise processed on the surface or inside. In addition, additional (including machine-readable) protective substances that are activated, masked, partially destroyed or removed as a result of processing when creating the first image with a kipp effect and / or the second image can be embedded in and / or applied to the base material with a kipp effect. Such additional protective substances in a preferred embodiment form another image with a kipp effect.

In this regard, it should be noted that the security element can have any basis suitable for processing by metallographic printing. Most preferred are foundations of paper and paper-like materials. There are no restrictions on the type of paper, and therefore, paper of ordinary varieties from the fibers of annual plants, especially cotton or cellulose fibers, can be used as the basis for the security element. Similarly, paper grades that are at least partially composed of synthetic fibers, preferably polyamide fibers, i.e. grades of paper, in which the share of polymer material is from 0 to 100 wt.%. The paper may also be coated on one or both sides with polymer films.

Typically, the paper layer has a density of from 50 to 100 g / m ² , preferably from 70 to 90 g / m ² . Obviously, depending on the purpose, paper of any desired density can be used. In addition, the paper may be single-layer or multi-layer. When using multilayer paper, its individual layers can be formed by paper of the same or different grades and, in turn, can also be coated with polymer films.

In addition, the base of the security element may be a polymer film, for example a polyester film. Such a film may further be a uniaxial or biaxial oriented film. Orientational stretching of the film allows, among other things, to give it polarizing properties, which can be used as another protective feature. Aids necessary to detect such properties, for example polarizing filters, are known to those skilled in the art.

The film can also be made in the form of a lining, occupying a separate section of the surface of the base, or in the form of a strip extending along the entire length or width of a document protected from forgery. As materials for the manufacture of the film, it is possible to use primarily polymers, primarily polyethylene terephthalate, polybutylene terephthalate, polyethylene naphthalate, polypropylene, polyamide, polyethylene. The film may be further subjected to uniaxial or biaxial orientational stretching.

As the basis of the security element, it may also be appropriate to use a multilayer material, at least one layer of which is formed by paper or paper-like material. A characteristic feature of such a multilayer material is that it has an exceptional high strength, the presence of which is preferable from the point of view of the durability of the security feature and due to which, in addition, the reliability of protection against counterfeiting is increased.

As the basis of the protective element, you can use a multilayer composite material that does not contain paper. Such materials can be effectively used in certain climatic zones of the Earth.

All materials used as the basis of the protective element may contain additives that serve as signs of authenticity. We are primarily talking about luminescent substances that are mostly transparent in the visible region of the spectrum, but which, when excited by the radiation of the invisible region of the spectrum using a suitable aid for this purpose, such as a source of ultraviolet or infrared radiation, can emit visible or detectable at least with the help of auxiliary means, luminescent radiation. Effective use of other protective signs is also possible, provided that they do not impair or only slightly impair the visual impression created by the print when it is examined.

Beneath / above the elements forming an image with a kipp effect, other layers can be placed that reproduce a pattern or image, but basically made flat or matched with a raster image with a kipp effect. In this way, for example, when examining a protective element at a right angle, it is possible to distract the attention of a person from the actual information reproduced due to the kipp effect and becoming noticeable in this case only when the protective element is tilted.

The steepness of the side surfaces of the first and second embossed elements affects the tensile strength of the base. The steeper each of the side surfaces of the embossed elements, the more embossed the base and the greater its elongation in this section, where it therefore has a reduced thickness and a reduced tensile strength.

In addition, the angle between the longitudinal direction of the first embossed structure and the printing cylinder of the printing machine affects the likelihood of paper damage in the manufacture of the security element. So, for example, at the indicated angle equal to 0 °, i.e. when the longitudinal direction of the first embossed structure is oriented parallel to the printing cylinder, there is a particularly high probability of paper damage. However, at such an angle, the most preferable conditions are created for observing the kipp effect, since the security element, for example, a banknote, does not need to be rotated around a vertical axis relative to the person for direct observation of the kipp effect. Therefore, the specified angle is preferably chosen equal to about 10 ° or about 45 °. When the first embossed elements are made not straight but, for example, wavy, the longitudinal direction of the first embossed elements means their averaged longitudinal direction.

The embossed structures according to the invention are carried out using an embossing tool with first recesses into which second recesses are at least partially integrated. In this case, either the second recesses are integrated into the first recesses by partially changing their geometry, or each of the second recesses is adjacent at a certain angle to the side surface of the first recesses, as a result of which they correspond with the corresponding embossed structures of the protective element.

In a preferred embodiment, the embossing tool is an embossing stamp or a printing form, especially a metallographic printing form, and has recesses that are made by engraving its surface. The engraved recesses in this case have a triangular, trapezoidal, sinusoidal or semicircular profile in cross section.

The first and second recesses on the surface of the embossing tool are most preferably performed with a stylus, and / or a laser, and / or etching in separate technological operations or in one technological operation. The depth of the recesses is about 50% of their width, in particular from 10 to 250 microns, preferably from 50 to 120 microns, most preferably from 60 to 100 microns.

The geometry of the working part of the engraving tool determines the steepness of the side surfaces of the embossed elements. So, in particular, replacing engraving tools, in the simplest version it is possible, for example, to obtain a steep right side surface of the embossed elements, use a special engraving tool with an acute angle at the top of its working part, and to obtain a flat left side surface of the embossed elements, an engraving tool with obtuse angle at the top of its working part.

A significant advantage of the invention is to obtain integrated additional information in the form of a second kipp effect created by the second embossed structure, the embossing elements forming which are located on the side surfaces or at the side surfaces of the first embossed elements. The visual visibility of such additional information can be further enhanced by the acceptable placement of the coating. According to the invention, this provides a clear binding of the second information to the geometry of the first embossed structure. Due to the special implementation of the coating and the second embossed structure within the first embossed structure, a change in their interaction is visually perceived relative to the surrounding background.

The advantage of the invention is, therefore, in the possibility of creating protective elements for information carriers in this way, combining two interconnected kipp effects and allowing the possibility of their manufacture on machines existing in a conventional printing press with a characteristic speed of work.

Other advantages of the invention include the possibility of implementing linear or non-linear color kipp effects, as well as the possibility of realizing many color combinations through the use, respectively partial use, of existing paints in the manufacture of an information medium. In addition, it provides good visual distinguishability of the proposed in the invention kipp effects for the average person, respectively, for the consumer without the use of auxiliary means.

The security element proposed in the invention is mainly intended to increase the degree of protection of valuable documents against forgery, such as, for example, banknotes, checks, stocks, identity cards, entrance tickets, travel tickets, certificates, credit cards, check cards and other similar valuable documents.

The inventive structure with optically variable properties can, in particular, be used on a valuable document in combination with any other security feature. So, for example, the structure with optically variable properties of the invention can be applied to a security thread, can be used in combination with a hologram or other diffraction structures, or can be placed next to or superimposed with other structures with optically variable properties.

The advantages of the invention are described in more detail below on the example of various preferred options for its implementation with reference to the accompanying description of the schematic drawings, which show:

figure 1 - proposed in the invention structure with optically variable properties formed by the first embossed structure, which is superimposed on the second embossed structure,

figure 2 is a combination of coating and embossed structure on the example of the first three embossed elements,

figure 3 is a combination of coating and embossed structure on the example of the location of the first embossed elements over a large area,

in Fig.4 - various types of depicted in Fig.3 combinations of coating and embossed structure when viewed from different directions and

figure 5 - various options for single and multi-color coatings.

In the embodiments of the invention considered in the following examples, for purposes of clarity, only the most important information is presented, which is necessary to clarify the essence of the invention, and the images shown in the drawings are presented in an extremely simplified schematic form and do not reflect real relationships between sizes. First of all, it should be noted that the proportions shown in the drawings do not correspond to the real size ratios and serve solely for a more visual explanation of the principles underlying the invention. In the practical implementation of the invention, much more complex patterns or graphic images applied by single or multi-color printing can be used as a coating. The same applies to embossed structures. Likewise, instead of the information considered in the following examples, which carries some semantic content, you can use graphic or textual information of any complexity.

The following examples present preferred embodiments of the invention, which, however, do not limit its scope. In this regard, it should be noted first of all that the various embodiments of the invention discussed in the following examples are not limited to their use as described below, but can also be used in various combinations to enhance these or those effects.

Figure 1 shows the structure of the invention with optically variable properties, formed by the first embossed elements 1, which are integrated or superimposed on the second embossed structure. The individual first embossed element 1 has a triangular cross section and therefore generally has the shape of a lying wedge with two inclined side surfaces. Each of both of these side surfaces has a color different from the color of the other side.

In the embodiments shown in FIGS. 1a-1b, the second embossed structure 2 is integrated into the first embossed element 1 by partially changing its geometry.

In the embodiment shown in FIG. 1 a, the second embossed structure 2 is formed by modulating the height of the first embossed element 1 in its longitudinal direction. In this case, the upper edge of the first embossed element 1 has wave-like depressions, in the area of which the side surfaces therefore have a smaller slope. When light falls on top of the first embossed element 1 at a right angle, the light falls on the lateral surfaces having a different slope and is therefore reflected by them at different angles. As a result of this, the kipp effect that occurs when the protective element is tilted in one or the other direction around the longitudinal axis of the first embossed element 1 is expressed with varying degrees along its longitudinal axis.

In the embodiment shown in FIG. 1 b, the second embossed structure 2 is formed by modulating the height of the first embossed element 1 in its transverse direction. Moreover, the upper edge of the first embossed element 1 is smoothed or dull in certain areas, i.e. executed with flatness. Such a smoothed area may, for example, have a different color than the color of the side surfaces, as a result of which, when the protective element is tilted in one or the other direction around the longitudinal axis of the first embossed element 1, in addition to the kipp effect created by the side surfaces, when the smoothed area is hit in the field of view, when looking at it from above at a right angle, its color is visible. In the same areas with optically variable properties of the structure, in which there is no second embossed structure 2, when the protective element is tilted to one or the other side around the longitudinal axis of the first embossed element 1, only both of its side surfaces are alternately visible, i.e. only the first kipp effect is observed.

In the embodiment shown in FIG. 1B, the second embossed structure 2 is made in the form of a groove-like depression at the top of the wedge in its longitudinal direction. In this case, the embossed structure 2 forms a longitudinal groove parallel to the upper edge of the first embossed element 1. The lateral surfaces of the hollow or longitudinal groove have a color that contrasts with the color of the adjacent side surface of the first embossed element 1. As a result, when the protective element is tilted around the longitudinal axis of the first embossed element, the first side surface of the first embossed element 1 is visible, and at the end of the first range of angles of view, the first side surface of the cavity extending further is visible parallel or almost parallel to the first side surface of the first embossed element. With a further inclination of the security element around the longitudinal axis of the first embossed element, the second side surfaces of the first embossed element 1 and depressions also enter the field of view, remaining visible until ultimately the first side surface of the first embossed element 1 and then the second side surface the depressions will not be covered by the second lateral surface of the first embossed element.

In the embodiments shown in FIGS. 1d-1g, the second embossed structure is formed by the second embossed elements 3, 4, 5 or 6, each of which adjoins at a certain angle to one of the side surfaces of the first embossed element 1. The second embossed element can be made, for example, as

- having the shape of a quarter of a sphere or an ellipsoid of an embossed element 3 in accordance with the variant shown in FIG. 1d, while it can also be shaped into any other segments, respectively parts of a sphere or an ellipsoid,

- a wedge-shaped embossed element 4 in accordance with the embodiment shown in FIG. 1e, resting on the surface of its cross section and adjoining its first embossed element with its one side surface,

- a pyramidal embossed element 5 in accordance with the variant shown in FIG.

- a wedge-shaped embossed element 6 in accordance with the variant shown in FIG. 1g, resting on one of its three side surfaces and adjacent to the first embossed element by the surface of its cross section.

In this case, the second embossed elements 3, 4, 5 or 6 with their longitudinal axes can be perpendicular to the longitudinal axis of the first embossed element 1, as, for example, in the embodiment shown in FIG. 1g, or inclined at any angle to it.

FIG. 2 shows a combination of a coating and an embossed structure using the first three embossed elements as an example 1. In FIG. 2 a and FIG. 2 b, a coating is shown in their upper part, a combination of a coating and an embossed structure is shown in the middle part, and in the lower part axonometric parts of the top shows a combination of coating and embossed structure.

The coating in the embodiment shown in FIG. 2a consists of continuous strips 8 parallel to the longitudinal axis of the first embossed elements 1, and discontinuous strips 7 parallel to the longitudinal axis of the second embossed elements 4. Discontinuous strips 7 are printed on one side surface of the second embossed elements 2, and solid strips 8 are printed on the side surface of the first embossed elements 1, which is located on the opposite side from the second embossed elements 4. In another embodiment, the coating according to the embodiment shown in FIG. 2b can also be made in the form of continuous strips 9 parallel to the longitudinal axis of the second embossed elements 4. Such continuous strips 8 are printed without breaks on one of the side surfaces of the second embossed elements 2, and the side surface the first embossed elements 1, located on the opposite side from the second embossed elements 4 of the side, does not have such a coating.

As a result, when the protective element is rotated around its vertical axis, i.e. axis perpendicular to its surface, creates an additional kipp effect. Moreover, in one range of angles of view, only the side surface of the second embossed elements 4 is visible with discontinuous strips 7 printed on it, or solid strips 9, and in the other range of angles of view, only the unsealed side surface is visible.

Figure 3 shows a combination of a coating and an embossed structure using an example of the arrangement of the first embossed elements shown in Fig. 2a over a large area. Moreover, in the cases shown in FIGS. 3b-3d, the coating in the form of a background impression 10 relates the first embossed structure in the form of the first embossed elements 1. The second embossed structure in the form of the second embossed elements 4 reproduces additional information 11, which in this example is a rectangle either a Roman numeral or the Latin letter "I". On fig.3d in the form of a circle circled in fig.3g a fragment shows a separate element with optically variable properties.

When examining the structure shown in FIG. 3 with optically variable properties from different directions A, B and C indicated in FIG. 4, different patterns are visible. So, in particular, according to figb when viewed from direction A, a continuous horizontal strip 8 is visible on the side surface of the first embossed structure 1, and when viewed from direction B, a regularly located pattern of discontinuous strips 7 and spaces between them is visible, also continuing on the side the surfaces of the second embossed structure 4 superimposed on the first embossed structure 1. In addition, when viewed from the direction C, a regularly located pattern is seen from the direction of the first embossed structure 1 7 grained strips and spaces therebetween. However, on the side surfaces of the second embossed structure, if you look from this direction, there is no print, and therefore a gap in this area is visible in the form of additional information 11.

Figure 5 shows various options for single and multi-color coatings. Different colors of the color coating, in this case, due to the impossibility of their real reproduction in the drawing, are represented on it by various gray tones and shading that replace them. In this case, the color of the schematic image may vary, and it may contain smaller elements, such as microstrings or dots, fragments or special characters. So, for example, in one embodiment, the black surface may correspond to the blue primary color, the gray surface to purple, and the hatched surface to yellow. Theoretically, there are no restrictions on the choice of colors.

On figa shows a single-color coating, consisting of single-color strips that are arranged in the form of a raster with step X and the width of which is less than step X of the raster. There is no paint between the individual strips, and therefore the color of the base is visible in these areas.

In Fig.5b, the coating is formed by an alternating sequence of two, and in Fig.5e of three strips of different colors. The pitch of the raster, in the form of which the strips are located, is greater than their width, and therefore there are gaps between the individual strips. In each of the gaps between the individual strips, there is no paint, and therefore the color of the base is visible in these areas. On figv and 5d between the individual strips there are no gaps, and therefore the individual strips directly border each other.

In FIGS. 5g and 5g, the multi-color coating is formed by a single-color background print, on top of which a single-color pattern from the lines shown in FIG. 5a is printed, respectively, a multi-color pattern from the lines shown in FIG. 5b.

In contrast, FIGS. 5g and 5i show a multi-color background print, which is shown in FIG. 5e, respectively, FIG. 5e and over which a single-color coating of the strips shown in FIG. 5a is printed.

Fig. 5k shows a coating that consists of an alternating sequence of stripes and repeating elements such as circles and rectangles.

Claims (31)

1. A security element with an optically variable structure formed by a first embossed structure, which consists of the first embossed elements and which is combined with a coating that contrasts with the surface of the security element so that at least individual sections of the coating are visible when viewing the security element at an angle, lying in the first range of angles of view, but at least partially hidden when viewed at an angle lying in the second range of angles of view, resulting in and by tilting the security element to one side and the other around the first axis, the first kip effect is observed, characterized in that the optically variable structure is also formed by at least one second embossed structure, which is located within the first embossed structure and creates, in addition to the first -effect is the second kipp effect and which is integrated into the first embossed elements by partially changing their geometry or consists of the second embossed elements, each of which is adjacent to the definition ELENITE angle to the side surfaces of the first embossed elements. 2. The protective element according to claim 1, characterized in that the second kipp effect manifests itself in addition to the first kipp effect when examining the protective element within the first or second range of viewing angles or when switching from the first to the second or from the second to the first range of angles view. 3. The security element according to claim 1, characterized in that at least one second embossed structure, when it is integrated into the first embossed elements by partially changing their geometry, is integrated into the first embossed elements by modulating their height in the longitudinal direction, and / or their height in the transverse direction, and / or their width, and / or the inclination of their side surfaces. 4. The security element according to claim 3, characterized in that the first embossed elements have a width changed by modulation and / or a tilt of their side surfaces on one or both sides changed by modulation. 5. The security element according to claim 1, characterized in that the first and second embossed structures are made in the form of raster structures, primarily in the form of a linear raster with a constant lineature. 6. The security element according to claim 5, characterized in that the first and second embossed elements have a triangular, trapezoidal, sinusoidal or semicircular profile in cross section. 7. The security element according to claim 1, characterized in that at least one second embossed structure is divided into separate sections. 8. The security element according to claim 1, characterized in that at least one second embossed structure is combined with a second coating contrasting with the surface of the information medium. 9. The protective element according to claim 1, characterized in that the height and / or lateral size of the embossed structures is / is more than 30 microns. 10. The security element according to claim 1, characterized in that the embossed structure is made in the form of blind embossing or halftone blind embossing. 11. The protective element according to claim 1, characterized in that the embossed structure is made in the form of colorful embossing. 12. The security element according to claim 1, characterized in that the second embossed structure and / or contrast coating is made / made in the form of a graphic and / or alphanumeric image. 13. The security element according to claim 1, characterized in that the embossed structures have linear embossed elements and / or non-linear embossed elements, which are made straight, wavy and / or curved in the longitudinal direction. 14. The protective element according to claim 1, characterized in that the contrast coating is made in the form of lines. 15. The security element according to 14, characterized in that the embossed structure and the contrasting coating are characterized by the same or similar or different spatial frequency. 16. The security element according to claim 1, characterized in that beneath and / or above the elements forming the image with the kipp effect, other layers are arranged that reproduce the pattern or image, but which are mainly consistent with the image with the kipp effect. 17. The security element according to claim 1, characterized in that it has a single or multilayer base. 18. The security element according to claim 17, characterized in that the base is coated and / or sealed and / or glued and / or laminated and / or laminated in one or more layers. 19. The protective element according to claim 17 or 18, characterized in that additional protective substances are activated and / or masked, partially destroyed or removed as a result of processing when creating the first image with a kipp effect and / or applied to the base material or a second image with a kipp effect. 20. A method of manufacturing a protective element according to one of claims 1 to 19, characterized in that a coating is applied to the basis of the protective element by printing, individual colors of which are simultaneously or sequentially applied by printing to the basis of the protective element. 21. The method according to claim 20, characterized in that the coating is applied by a flat printing method, such as, for example, offset printing, letterpress method, such as, for example, printing or flexographic printing, screen printing, gravure printing, such as for example, as autotypic intaglio printing or metallographic printing, or by the method of thermographic printing, such as, for example, the thermal transfer method. 22. The method according to item 21, wherein the axis of the printing cylinder is positioned at an angle to the longitudinal direction of the first embossed elements of approximately 10 ° or approximately 45 °. 23. The method according to claim 20, characterized in that the embossed structure is performed with an embossing tool. 24. The method according to item 23, wherein the embossed structure is performed by metallographic printing or a thermal method. 25. The method according to claim 20, characterized in that they use printing inks with high transmittance. 26. The method according to claim 20, characterized in that the basis of the protective element is either embossed and sealed in one run, or is first embossed, and then sealed, or is first sealed and then embossed. 27. An embossing tool with first recesses, characterized in that at least part of the first recesses are at least partially integrated second recesses, which are integrated into the first recesses by partially changing their geometry or each adjacent at a certain angle to the side surface of the first recesses . 28. An embossing tool according to claim 27, characterized in that it is an embossing stamp or a printing form, primarily a metallographic printing form, and the recesses are made by engraving the surface of the embossing tool. 29. An embossing tool according to claim 27 or 28, characterized in that the first and second recesses have a triangular, trapezoidal, sinusoidal or semicircular profile in cross section. 30. An embossing tool according to claim 27 or 28, characterized in that the depth of the recesses is approximately 50% of their width. 31. An embossing tool according to claim 27 or 28, characterized in that the depth of the recesses is from 10 to 250 microns, preferably from 50 to 120 microns, most preferably from 60 to 100 microns.

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