RU2427472C2 - Protection element with structure having optically variable properties - Google Patents

Abstract

FIELD: printing industry.

SUBSTANCE: protection element with structure having optically variable properties and formed with embossed structure is described. Such embossed structure is combined with the coating contrasting with information medium surface so that at least some sections of the coating are seen when viewing the protective element at straight angle, but unseen at its being viewed at the specified acute angle. As a result, at alternating viewing of protective element at straight and angles, tilt effect is observed. Coating is formed with solid-line multicoloured screen-type pattern and reproduces at least one first information, and embossed structure is not solid and reproduces at least one second information; at that, the first information and the second information are partially mutually overlapped.

EFFECT: protection element provides increased protection degree against forgery and copying owing to masking the mismatchings occurring in colour register between elements.

42 cl, 3 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 information carrier in such a way that at least individual parts of the coating are visible when viewing the security element from a right angle of view, but are not visible when viewed from a given sharp angle of view. As a result, when alternately viewing the protective element at direct and acute angles of view, a kipp effect is observed.

Information carriers, such as, for example, banknotes, securities, credit cards, identity cards in the form of cards, passports, certificates and other documents, as well as labels, packages or other elements to protect various goods and products from counterfeiting, are provided for their purpose counterfeit protection, primarily with the help of color copiers or other equipment for reproduction, with protective elements with optically variable properties. The protection against falsification is based on the fact that the above devices for reproducing are not capable or are only capable of insufficiently accurately reproducing an optically variable effect, which is easily and clearly distinguishable visually. Protective elements with optically variable properties primarily have the corresponding characteristic tactile properties, which are difficult to copy but easy to verify without the use of auxiliary means.

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. The combination of an optically variable effect created by a combination of background and embossing, and an additional effect is distinguishable visually, but cannot be reproduced on photocopiers. In accordance with this, such a set can serve as information on the basis of which it can be checked whether a particular document is authentic; accordingly, if one or several optically variable effects are present, it is possible to exclude the possibility that the checked document was made on commercially available reproducing equipment.

An information carrier with a security element is known from EP 1317346 B1, which is formed by means of a blind stamping using a metallographic printing method and for which a background print is applied to the information carrier by means of a metallographic printing, and then, during another printing process, the information carrier is subjected to grayscale blind embossing. In this case, there are discrepancies in the register, which can reach several millimeters. Such discrepancies in the register are masked by appropriately designed colored areas located around the grayscale blind embossing, observing the register relative to it. Such colored areas overlap the discrepancies in the register between the background print and the halftone blind embossing, which is therefore perceived by the human eye as centered in the background print with exact observance of the register relative to it.

A storage medium is known from WO 2004/022355, equipped with a structure having optically variable properties, which is formed by an embossed structure with relief projecting portions and a first coating contrasting with the surface of the storage medium. The embossed structure and coating are combined with each other in such a way that when viewing the information carrier alternately at direct and sharp angles of view, a kipp effect is observed. The first coating is provided only in certain areas. The structure with optically variable properties in at least some areas has a second coating, which also contrasts with the surface of the information carrier, which is applied to the first coating at least in some areas.

Known from WO 97/17211 or from WO 2004/022355, the coating is made mainly in the form of a linear raster of printed lines, which can have any color design. Lines of different colors are located indented from each other or close to each other. When making lines with a width of about 100 μm, they are almost no longer distinguishable by the human eye individually and therefore create a uniform color impression. So, for example, when performing a linear raster of regularly alternating lines of cyan, magenta, and yellow primary colors, when viewing the information carrier from a right angle of view, they create a visual impression of a uniformly painted gray surface.

However, a significant drawback of a linear raster of printed lines is the fundamental inevitability of mismatches in the register between lines of different colors, since the lines of each color are printed on a sequential basis. Even when using printing methods with high accuracy, register lines are minimally offset from each other, and therefore the surface of the coating formed by them looks striped and spotty, i.e. it does not give the impression of a uniform colored surface.

Since such mismatches in the register can also occur over the entire coverage area, masking them by printing colored areas over them in accordance with the solution known from EP 1317346 B1 is not possible.

Based on the foregoing, the present invention was based on the task of improving a security element with an optically variable structure formed by a linear raster coating, as well as an embossed structure, to mask mismatches in the register that fundamentally arise between the elements forming the coating.

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

According to the invention, a structure having optically variable properties is formed by a coating formed by a continuous linear multicolor, i.e. at least a two-tone, raster structure, and embossed texture. Moreover, the coating and embossed structure reproduce at least one visually perceptible information. In addition, the information reproduced by the embossed structure and the information reproduced by the coating partially overlap.

An advantage of the structure with optically variable properties of the invention is that the information reproduced by the coating distracts attention from inconsistencies in the register register. Although there are mismatches in the register, as before, because of which it, as before, looks striped and spotted, nevertheless, the person’s gaze focuses primarily on the information reproduced by the coating.

A continuous linear multicolor raster structure forming a coating reproduces at least one first information transmitted by a negative (reverse) and / or positive image obtained by modulating the lines of the raster structure. According to the invention, the modulation of the line consists in changing the appearance of the line, primarily in changing its shape, color and / or direction. The negative image according to the invention is obtained primarily by reducing, and the positive image by increasing the line width. Separate lines of the raster structure are modulated in certain areas in such a way that an impression of a graphic or alphanumeric image is created. When looking at the information carrier, respectively, the protective element provided on it from a normal distance of 30-50 cm, the human eye can see, for example, a number, a letter, a portrait image, an animal image, a plant image, a landscape image or an image of a structure.

When viewing such an image from a much smaller distance of a few centimeters or under a magnifying glass, you can see that the lines are modulated by the type of dot pattern. So, for example, lines can change their size in a certain area in a direction parallel to the surface of the base of the information carrier, i.e. change its width by thinning or thickening. Alternatively, or in addition to this, the lines may also have gaps or an angled shape, may be formed by a sequence of short gaps and points, rectangles, symbols or other similar geometric shapes or alphanumeric characters, or may have offsets along their length. Likewise, lines can significantly change their color or its saturation, i.e. can be applied with paint with a varying thickness of its layer. In addition, these varieties of line modulation can also be combined with each other, for example, the line can be dashed in the corresponding section in a different color or can be performed with a gap, which can be partially filled again by a sequence of font characters, numbers and dots.

The lines of the pattern formed by them can directly adjoin each other or can stand apart from each other. In the first case, a pattern of lines covering its entire area is applied to the storage medium, preferably in the form of an alternating sequence of three lines of cyan, magenta and yellow primary colors or other similar color design. 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 color basis of the information carrier an alternating sequence of two adjacent blue and yellow lines, leaving an interval between each pair of lines, the basis of the information carrier forms an “absent” 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.

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.

In a preferred embodiment, the coating also has machine-readable features. Such machine-readable security features contain, at the same time, protective (characteristic) substances that can be automatically detected, primarily reflective, magnetic, electrically conductive, absorbing x-rays, phosphorescent, fluorescent or other luminescent substances.

Under the substances that can be automatically detected, in the most preferred embodiment, it is meant luminescent, electrically conductive, absorbing infrared radiation or absorbing x-ray radiation substances, since such materials make it possible to detect them in a non-contact way. Thus, when automatically checking the information carrier for the presence of such materials, neither the document encoded by them nor the sensor are subject to wear, and the latter aspect is of particular importance primarily when automatically checking banknotes that are checked in extremely large quantities. In addition, frequent contact checks of documents could lead to signs of wear on them. As a result, such a trace of wear formed on the document during its frequent verification could become noticeable and could unmask the location of the code, which is possibly not visible otherwise. Therefore, luminescent and electrically conductive substances, partly also absorbing infrared radiation, are most suitable for use as coding materials and for the reason that they can, for example, be added in the form of particles to printing inks without any noticeable change in the color impression created by them. Moreover, printing inks, when added, for example, colorless or having only a weak intrinsic color of luminescent protective substances or practically colorless electrically conductive polymers, retain the richness of their colors. In addition, many luminescent substances, electrically conductive particles, and absorbing infrared or x-ray radiation substances have a positive property for a long time to maintain their ability to luminescence, respectively, their conductivity, respectively, their absorption capacity, which remains constant and neither changes nor is lost under the influence of external factors .

Mainly mica particles with an electrically conductive coating are suitable for use as electrically conductive substances. For use as an X-ray absorbing material, for example, barium sulfate is suitable. As infrared absorbers, organic absorbers, for example, from the group of phthalocyanines, and inorganic absorbers, such as, for example, carbon in the form of soot or graphite, can be used.

The line width is from 30 to 300 μm, preferably from 40 to 200 μm, and therefore, from a distance of at least 30 to 50 cm, the raster structure is no longer perceived by the human eye as consisting of separate lines, but creates a uniform color impression. The engraving depth of the lines of the pattern they form, i.e. the immersion depth of the engraving tool in the preform of the printing plate during its engraving is from 15 to 250 microns, preferably from 40 to 150 microns, most preferably from 80 to 120 microns.

According to the invention, the embossed structure is located on a separate coating area, i.e. unlike him, it is not continuous. The embossed structure may be partially located outside the coating, thereby going beyond it.

The embossed structure reproduces at least one information, the so-called second information, which is transmitted by the contours of the embossed sections. The second 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.

In a preferred embodiment, the embossed structure is in the form of a 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.

In another preferred embodiment, the embossed structure is 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 form are filled with ink. Excess ink is removed from the printing form with an eraser roller or squeegee, leaving the linear (i.e. line-shaped) engraved indentations filled to the brim 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 recesses of the printing form filled with ink 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. 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 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 grabs the ink from the recesses, but is also embossed, acquiring a relief structure.

In principle, embossed structures are performed by an embossing tool, such as a metallographic printing form, an embossing stamp or a plate. In this case, there are recesses on the surface of such an embossing tool, performed by mechanical engraving and / or by laser ablation and / or by scribing (notching or piercing), for example, with a diamond cutter, and / or by etching the surface of the embossing tool.

Embossing can also be done with thermo methods. In this case, the plastic or polymer base of the information carrier 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 one particularly preferred embodiment, the embossed structure is 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, 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 performing a recess with a triangular profile, two side surfaces are formed, which are simultaneously visible when viewing the information carrier from a right angle. When viewing the information carrier from an acute angle of view, only one side surface is visible, since the other side surface is closed by the opposite, visible side surface. Thus, when alternately viewing the information carrier at direct and sharp 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 structure is 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 information carrier 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.

According to the invention, the first information and the second information partially overlap. The first information and the second information are primarily two graphic or alphanumeric images of different sizes, while the first information is larger in the longitudinal direction and / or transverse direction than the second information. Thus, the first information is partially located within the second information, and partially extends beyond it.

In principle, it is necessary to avoid the execution of the first and second information of the same size, as well as their direct overlap on top of one another and at the same time their complete overlap or placement of the first information completely within the structure that reproduces the second information. With this arrangement of the first and second information, basically only the information reproduced by the embossed structure would be visually perceived, and the information reproduced by the coating would be ignored, respectively, would disappear, due to which the solution to the problem based on the invention, consisting in diverting attention from mismatches in register coatings would become impossible.

Both stages of fabricating a structure with optically variable properties, which are embossing and printing, can be performed in any order. So, 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 emboss the structure on the basis of the information medium. Both stages considered can be performed simultaneously, combining them into one stage.

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.

A particular advantage of the invention is that the first information allows you to divert attention from the mismatch in the register coat.

An advantage of the structure with optically variable properties of the invention is that the information reproduced by the coating distracts attention from inconsistencies in the register register. Although there are inconsistencies in the register between the individual lines that make up the coating, as a result of which the coating, as before, looks striped and spotty, nevertheless, the person’s gaze focuses on the first information in the form of a graphic or alphanumeric image. The first information in the form of a graphic or alphanumeric image, thus, attracts much more attention than the mismatch in the register, and thereby allows you to not notice them.

Another advantage of the invention lies in the fact that a structure having optically variable properties when viewing a data carrier or a security element from a right angle of view substantially wins in attractiveness. A structure with optically variable properties is not only formed by a structureless background and embossed, but also complemented by a graphic or alphanumeric image. A related advantage is the possibility of better integration of a structure with optically variable properties into the existing design of a valuable document, since the patterns or images provided on the valuable document can be made in the form of a coating, which is one of the components that form the structure with optically variable properties, or continue in him.

Similarly, the multicolor of the coating can be used to change the general appearance of the information carrier alone, respectively, of the security element in reflected light, for which the selected pair of colors, for example, cyan and magenta, is not subjected to any changes, but instead only yellow is modified , which allows us to more strongly highlight the color component formed by a combination of cyan and magenta, i.e. blue color. In this way, other colors can be obtained by shifting the color accent in the direction of yellow, red or blue, respectively, and thereby further enhance the overall visual impression created by a valuable document, such as, for example, a banknote.

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 - having optically variable properties of the structure proposed in the invention modulation of the lines forming the coating,

figure 2 - image illustrating the various modulation possibilities of the lines forming the coating, and

figure 3 is a three-color linear raster with blind embossing in the form of the number "50" and with the modulation of the linear raster image in the form of an eagle.

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.

In one of the preferred embodiments shown in FIG. 1, the optically variable structure provided with the storage medium is formed by a coating 4 and an embossed structure 6.

Coating 4 is formed by an alternating sequence of three repeating lines of 1, 2, and 3 cyan, yellow, and magenta. Several yellow lines 2 have a modulation in the form of broadening 5. Together, all such broadenings reproduce when viewed from a distance of about 30-50 cm, the first information in the form of an image of an alphanumeric character, in this case in the form of the letter "A".

1 and 2, images formed by lines, which are actually color, are shown in black and white. Therefore, in these drawings, primarily the colored lines are depicted in the form of black lines, which, for the possibility of delimiting them from each other, are shown spaced from each other. In reality, such lines for obtaining a coating 4, visually perceived in uniformly gray color, directly adjoin one another, which, however, cannot be displayed on a black and white image.

The embossed structure 6 is formed by individual linear embossed elements arranged parallel to forming the coating 4 lines and protruding above the surface of the base of the information carrier.

The embossed elements have two side surfaces 7 and 8 facing each other in opposite directions, which are located relative to each other like the sides of an isosceles triangle. At the same time, on the side surface 7 of each embossed element there is a part of the line 3 of magenta, and on its opposite side side 8 there is a part of the line 1 of blue color. At the top of each embossed element is part of the yellow line 2.

Accordingly, when examining such a structure with optically variable properties from an acute angle of view from direction A, only the side surfaces of 7 embossed elements and thereby magenta lines are visible in the embossed structure zone, and when examining structures with optically variable properties from an acute angle of view, In direction B, only the lateral surfaces of the 8 embossed elements are visible in this area, and thus the blue lines. When viewing the information carrier from a distance of about 30-50 cm and tilting to one side and the other in the embossed structure zone, only the purple side surfaces of the embossed elements, all three colors and only the blue side surfaces of the embossed elements are alternately visible.

Together, all embossed structures reproduce the second information in the form of an image of an alphanumeric character, in this case in the form of the letter "V".

Figure 2 schematically shows various examples of modulation of individual or several lines forming a coating 4. In this case, the drawing shows three lines 1, 2 and 3 of different colors as a fragment of their alternating sequence depicted in figure 1.

Below, the modulation of the lines is considered on the example of changing the length, thickness and structure of line 2. However, the remaining lines can be modulated in the same way.

On figa shows the modulation of line 2, which in a limited area has a gap 10. Line 1 and line 3 do not have modulation. The line break 10 is formed by a white space, on which ink is not printed on the basis of the information carrier, and therefore the color of the basis of the information carrier dominates in this place, in this example white.

In FIG. 2b, the gap formed by the line break shown in FIG. 2a is partially filled with several equally spaced squares 11. In FIG. 2b, the same gap is filled with a combination of squares 11 and points 12 not equally spaced from each other. The gaps between the squares 11, respectively dots 12 are formed by white spaces in which ink is not printed on the basis of the information carrier, and therefore the color of the basis of the information carrier dominates in this place, in this example white. However, in this case, the color of the base of the information carrier is less noticeable compared to the gap shown in FIG.

Instead of dots or squares, you can use any other symbols, for example, font characters, numbers, or geometric or graphic images. As an example of geometric or graphic images, stars, arrows, trefoil-like structures or fragments, i.e. structures with empty or white spaces.

In Fig.2d, in addition to the modulation shown in Fig.2b, the modulation of line 3 is also shown in the form of a gap, the gap formed by which is partially filled by several equally spaced points 12. In this case, the gaps between points 12 are also formed by white spaces, on which the base no ink was printed on the information carrier, and therefore the color of the base of the information carrier dominates in this place, in this example white.

On fig.2d and 2e shows the modulation of the width of line 2 in a certain section of it, on which in the example shown in fig.2d line 2 has a thinning 13, and in the example shown in fig.2e - broadening 14. The transition between sections of different widths can be sharp, as shown in fig.2d and 2e examples, or smooth over a certain transitional section.

The gaps between the thinned part of line 2 and the adjacent lines 1 and 3 in the example shown in FIG. 2e are formed by white spaces in which ink is not printed on the basis of the information carrier, and therefore the color of the basis of the information carrier dominates in this place, in this example white color.

The broadening 14 of line 2 in the example shown in FIG. 2e enters adjacent lines 1 and 3 and partially overlaps with them, drowning them.

In the example shown in FIG. 2g, the modulation of line 2 is its offset 15. Line 2, in different sections of it, is at different distances from the neighboring lines 1 and 3, namely: the part of line 2 located to the right of offset 15, not offset and therefore equidistant from line 1 and line 3, and the part of line 2, located to the left of offset 15, is spaced from line 1 by an increased distance, and from line 3 by a reduced distance.

The gap between lines 2 and lines 1 in a portion of increased distance between them is formed by a blank area in which ink is not printed on the media carrier, and therefore the color of the media carrier dominates in this place, in this example white. At the same time, in the area with a reduced distance between line 2 and line 3, line 2 enters line 3 and partially overlaps with it, drowning it.

The transition between sections with different distances from adjacent lines, and in this case, can be sharp as a break point, as in the example shown in Fig.2g, or smooth over a certain transition section.

In the examples shown in FIGS. 2a-2g, the non-modulated lines are solid. However, such a condition is not strictly necessary for the implementation of the invention. Moreover, non-modulated lines can also be done with dashed, dashed, dashed-dotted lines, or they can consist of any other combinations of discontinuities and structural elements. The foregoing is illustrated in FIG. 2z by the example of broken lines 21, 22 and 23, which consist of squares and gaps arranged in a row. The modulation of the lines in this case consists in replacing the structural elements in the form of squares with points 12 and in changing their sizes with replacement for small points 16 or the smallest points 17. Similarly, you can use all the other types of line modulation discussed above.

Other, but not possible, but also possible types of modulation include, first of all, distortions of individual sections of lines, changing the line shape from straight to zigzag, or changing the color of the line, for example, from yellow to blue or from light yellow to dark yellow.

Figure 3 schematically shows a specific embodiment of the proposed invention the structure with optically variable properties. The coating 4 is thus made similar to that shown in figure 1 in the form of a three-color linear raster formed by parallel lines of cyan, yellow and magenta.

When considering a protective element with a similar structure having optically variable properties from a distance of about 30-50 cm, the modulation 31 of the linear raster forming the coating 4 is visually perceived as an eagle with spread wings. Modulation 31 in this case consists in

- partial thinning of the blue lines, in connection with which the white background color of the basis of the protective element, respectively, of the basis of the information carrier dominates in this section,

- partial broadening of the yellow lines on one side facing the magenta lines, i.e. from the side of the blue lines, the yellow lines are not broadened, and

- partial thinning of the purple lines, since they overlap with yellow lines due to their partial broadening.

The structure with optically variable properties is additionally formed by an embossed structure 30, the contours of which are visually perceived as the number "50".

The embossed structure 30 and the modulation 31 partially overlap, while the modulation 31 is partially located within and partially outside the contours of the embossed structure 30.

Claims (42)

1. A security element with an optically variable structure formed by an embossed structure that is combined with a coating that contrasts with the surface of the information carrier so that at least some areas of the coating are visible when viewing the security element from a right angle, but are not visible when viewed at a given sharp angle of view, as a result of which, when alternately viewing the protective element at direct and acute angles of view, a kipp effect is observed, which differs in that the coating is formed of linear continuous multicolour raster structure and reproduces at least one first information and the embossed structure is not continuous and reproduces at least one second information, the first information and second information partly overlap mutually. 2. The security element according to claim 1, characterized in that at least one first information is transmitted in a negative and / or positive image obtained by at least one modulation of the lines of the raster structure. 3. The security element according to claim 2, characterized in that the modulation of the lines of the raster structure consists of at least
- in modulation of the line width and / or
- in the implementation of the line with a gap and / or
- at least partially filling the gap formed by the gap with symbols and / or font characters, and / or numbers, and / or fragments, and / or
- in giving the line a curved shape, and / or
- in the implementation of the dotted line, and / or
- in changing the color of the line. 4. The security element according to one of claims 1 to 3, characterized in that the embossed structure is made in the form of blind embossing or halftone blind embossing. 5. The security element according to one of claims 1 to 3, characterized in that the embossed structure is made in the form of colorful embossing. 6. The security element according to one of claims 1 to 3, characterized in that at least one first and / or second information is made / made in the form of a graphic and / or alphanumeric image. 7. The protective element according to one of claims 1 to 3, characterized in that the lines of the pattern formed by them are directly adjacent to each other. 8. The protective element according to one of claims 1 to 3, characterized in that the lines of the pattern formed by them are spaced from each other. 9. The security element of claim 8, characterized in that at least one line of the pattern formed by them is formed by the background color of the basis of the information carrier. 10. The protective element according to one of claims 1 to 3, characterized in that the width of the lines of the pattern formed by them is from 30 to 300 microns. 11. The security element of claim 10, wherein the width of the lines of the pattern formed by them is from 40 to 200 microns. 12. The protective element according to one of claims 1 to 3, characterized in that the engraving depth of the lines of the pattern formed by them is from 15 to 250 microns. 13. The security element according to claim 12, characterized in that the engraving depth of the lines of the pattern formed by them is from 40 to 150 microns. 14. The security element according to item 13, characterized in that the engraving depth of the lines formed by them is from 80 to 120 microns. 15. The protective element according to one of claims 1 to 3, characterized in that the coating is formed by three parallel lines, at least one of which is structured. 16. The security element according to clause 15, wherein the lines have yellow, cyan and magenta colors or other similar color schemes. 17. The security element according to one of claims 1 to 3, characterized in that the embossed structure has linear embossed elements. 18. The security element according to claim 17, characterized in that the embossed structure is made wavy and / or curved. 19. The security element according to one of claims 1 to 3, characterized in that the embossed structure has non-linear embossed elements. 20. The security element according to one of claims 1 to 3, characterized in that the coating has machine-readable features. 21. The security element according to claim 20, characterized in that the machine-readable feature comprises protective substances capable of being automatically detected, primarily reflective, magnetic, electrically conductive, absorbing x-rays, phosphorescent, fluorescent or other luminescent substances. 22. A storage medium with a security element according to one of claims 1 to 21. 23. The storage medium according to p. 22, characterized in that it is a valuable document, especially a banknote. 24. The use of a protective element according to one of claims 1 to 21 or a storage medium according to claim 22 or 23 for protecting goods and products from counterfeiting. 25. A method of manufacturing a protective element with an optically variable structure formed by an embossed structure that is combined with a coating that contrasts with the surface of the information carrier so that at least individual sections of the coating are visible when viewing the protective element from a right angle, but are not visible when viewed from a given sharp angle of view, as a result of which, when the protective element is alternately examined at right and acute angles of view, Nos effect, characterized in that the coating form a continuous linear multicolor raster structure reproducing at least one first information and the embossed structure operate not continuous and reproducing at least one second information, the first information and second information partly overlap mutually. 26. The method according A.25, characterized in that the information is performed in the form of a graphic and / or alphanumeric image. 27. The method according A.25 or 26, characterized in that the first information is reproduced in the form of a negative and / or positive image. 28. The method according A.25 or 26, characterized in that the printing coating is applied to the basis of the protective element, respectively, to the basis of the information carrier. 29. The method according to p. 28, characterized in that the colors of the individual colors of the coating individually sequentially applied by printing on the basis of the protective element, respectively, on the basis of the information carrier. 30. The method according to p. 28, characterized in that the inks of individual colors of the coating are simultaneously applied by printing on the basis of the protective element, respectively, on the basis of the information carrier. 31. The method according to p. 28, characterized in that the coating is applied by the method of flat printing, such as 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. 32. The method according A.25, characterized in that the embossed structure is performed by blind embossing or halftone blind embossing. 33. The method according A.25, characterized in that the embossed structure is performed by colorful embossing. 34. The method according to p. 32 or 33, characterized in that the embossed structure is performed by an embossing tool. 35. The method according to p. 32 or 33, characterized in that the embossed structure is performed by metallographic printing. 36. The method according to p. 32 or 33, characterized in that the embossed structure is performed by a thermo-method. 37. The method according A.25 or 26, characterized in that the basis of the protective element, respectively, the basis of the information carrier is embossed and sealed in a single operation. 38. The method according A.25 or 26, characterized in that the basis of the protective element, respectively, the basis of the information carrier is first embossed and then sealed. 39. The method according A.25 or 26, characterized in that the basis of the protective element, respectively, the basis of the information carrier is first sealed, and then embossed. 40. An embossing tool, such as an embossing stamp or a printing form, with recesses on its surface, by which a protective element is made according to one of claims 1 to 21. 41. The embossing tool according to claim 40, characterized in that the recesses on its surface are made by mechanical engraving, and / or by laser ablation, and / or by scribing, and / or by etching. 42. The embossing tool according to claim 40 or 41, characterized in that it is a form of metallographic printing.

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