EP2853411A1 - Security element with lenticular image - Google Patents

Abstract

The invention contains a security element (20) for safeguarding security papers, value documents and other data carriers, having a representation arrangement for displaying one or more target images (14) whose motifs are each formed by visually recognizable, contrasting image areas (16, 17), wherein the The display arrangement comprises a lenticular grid and a motif image spaced from the lenticular grid which, when viewed with the lenticular array, displays the predetermined target images, the lenticular array formed from a plurality of spherical or aspherical microlenses (24) and the motif image formed from a plurality of unit cells (28) is. According to the invention, it is provided that the motif image comprises a plurality of reflective facets (33-1, 33-2) of at least one first and one second type which differ in their inclination and which, when viewed with the lenticular grid, visually discernible, contrasting image areas generate the target images; wherein the reflective facets of the first kind (33-1) have a tilt ² 1 given by the focal length of the microlens, the radius of curvature in the center of the microlens and the lens radius of the microlens, and the reflective facets of the second kind (33-2) have a tilt 2, which is given by | ² 1 - ² 2 | > 10 °.

Description

The invention relates to a security element for securing security papers, documents of value and other data carriers, having a representation arrangement for displaying one or more reference images whose motifs are each formed by visually recognizable, contrasting image regions. The invention also relates to a method for producing such a security element, and to a data carrier equipped with a security element.

Data carriers, such as valuables or identity documents, but also other valuables, such as branded articles, are often provided with security elements for securing purposes, which permit verification of the authenticity of the data carrier and at the same time serve as protection against unauthorized reproduction. Data carriers in the context of the present invention are in particular banknotes, stocks, bonds, certificates, vouchers, checks, high-quality admission tickets, but also other forgery-prone papers, such as passports and other identity documents, credit cards, health cards, as well as product security elements such as labels, seals, packaging and the like. The term "data carrier" in the following includes all such objects, documents and product protection means.

Security elements with viewing-angle-dependent effects play a special role in the authentication of authenticity since they can not be reproduced even with the most modern copiers. The security elements are equipped with optically variable elements that give the viewer a different image impression under different viewing angles and, for example, depending on the viewing angle, a different color or brightness impression and / or a show another graphic motive. For example, the security elements may include a tilt or swap image, a motion image, or a stereo image.

In this context, it is also known to provide data carriers, such as identity cards, for protection with laser-engraved tilting images. In this case, two or more different markings, such as a serial number and an expiration date, are laser engraved at different angles by an array of cylindrical lenses in the card. The laser radiation generates a local blackening of the card body, which makes the engraved markings visually visible. When looking at it, depending on the viewing angle, only the marking engraved from this direction is visible, so that an optically variable tilting effect is produced by tilting the card perpendicular to the axis of the cylindrical lenses.

For some time, so-called moiré magnification arrangements and other micro-optical representational arrangements have also been used as security features. The basic operation of Moire magnification arrangements is described in the article " The moire magnifier ", MC Hutley, R. Hunt, RF Stevens and P. Savander, Pure Appl. Opt. 3 (1994), pp. 133-142 , described. In short, moiré magnification thereafter refers to a phenomenon that occurs when viewing a raster of identical image objects through a lenticular of approximately the same pitch. As with any pair of similar rasters, this results in a moire pattern consisting of a periodic arrangement of enlarged and possibly rotated images of the elements of the image raster.

The use of reflective relief patterns in alternating image arrangements with cylindrical lenses is known, such. B. in the US 4,417,784 A1 is described. Depending on the inclination of the formed in the form of planar micromirrors juxtaposed sections of the relief pattern these are perceived light or dark. In order to achieve sufficient contrast, micromirrors with comparatively large inclinations are proposed for producing dark sections. The production of such structures, in particular the replication and the embossing of structures with a high aspect ratio (the aspect ratio is the ratio of maximum depth to minimum lateral extent), however, is not entirely unproblematic.

Based on this, the invention has for its object to provide a security element of the type mentioned, which combines a high security against counterfeiting with a high-contrast appearance and is less limited in terms of the manufacturing process.

This object is solved by the features of the independent claims. Further developments of the invention are the subject of the dependent claims.

mit $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{h}\right)}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}\right)},$$

wobei f die Brennweite der Mikrolinse, h die Höhe der Mikrolinse im Scheitel, R den Krümmungsradius im Zentrum der Mikrolinse und r den Linsenradius der Mikrolinse darstellen, und die reflektiven Facetten der zweiten Art eine Neigung β₂ aufweisen, die gegeben ist durch $$\left|{\beta }_1-{\beta }_2\right|>10°\mathrm{.}$$

According to the invention, the display arrangement of the above-mentioned security element comprises a lenticular and spaced from the lenticular motif image showing the predetermined target images when viewed with the lenticular, wherein the lenticular grid is formed of a plurality of spherical or aspherical microlenses and the motif image of a Plurality of unit cells is formed. Furthermore, according to the invention, the motif image comprises a plurality of reflective facets of at least a first and a second type which differ in terms of their inclination and which, when viewed with the lenticular grid generate the visually recognizable, contrasting image areas of the target images, wherein the reflective facets of the first type have an inclination β ₁ , which is given by $$0.85\cdot {\beta }^{*}<{\mathrm{<figure-callout\; id="1"\; label="\beta "\; filenames="imgf0001.png"\; state="\{\{state\}\}">\beta </figure-callout>}}_1<1.15\cdot {\beta }^{*}$$

With $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{H}\right)}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}\right)}.$$

where f is the focal length of the microlens, h is the height of the microlens at the apex, R is the radius of curvature in the center of the microlens, and r is the lens radius of the microlens, and the reflective facets of the second type have an inclination β ₂ given by $$\left|{\beta }_1-{\beta }_2\right|>10°\mathrm{,}$$

mit $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{h}\right)}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}\right)},$$

wobei f die Brennweite der zylindrischen Mikrolinse, h die Höhe der zylindrischen Mikrolinse im Scheitel, R den Krümmungsradius im Zentrum der zylindrischen Mikrolinse und r den Linsenradius der zylindrischen Mikrolinse (bzw. 2r die Ausdehnung der zylindrischen Mikrolinse in Richtung der zweiten Koordinatenachse) darstellen, und die reflektiven Facetten der zweiten Art eine Neigung aufweisen, deren Komponente β₂ in Richtung der zweiten Koordinatenachse gegeben ist durch $$\left|{\beta }_1-{\beta }_2\right|>10°\mathrm{.}$$

In a second aspect, the display arrangement of the generic security element comprises a lenticular screen and a spaced apart from the lenticular motif image showing the predetermined target images when viewed with the lenticular grid, wherein the lenticular grid is formed of a plurality of cylindrical microlenses, which are arranged in a grid by which a coordinate system having a first coordinate axis defined by the focal lines of the cylindrical microlenses and a second coordinate axis perpendicular to the first coordinate axis and the motif image formed by a plurality of unit cells is formed. Furthermore, the motif image comprises a plurality of reflective facets of at least a first and a second type, which differ in their inclination and which, when viewed with the lenticular screen, produce the visually recognizable, contrasting image areas of the target images, the reflective facets of the first type having an inclination whose component β _{1 is given} in the direction of the second coordinate axis by: $$0.85\cdot {\beta }^{*}<{\mathrm{<figure-callout\; id="1"\; label="\beta "\; filenames="imgf0001.png"\; state="\{\{state\}\}">\beta </figure-callout>}}_1<1.15\cdot {\beta }^{*}$$

With $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{H}\right)}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}\right)}.$$

where f is the focal length of the cylindrical microlens, h is the height of the cylindrical microlens at the apex, R is the radius of curvature in the center of the cylindrical microlens, and r is the lens radius of the cylindrical microlens (or 2r the extension of the cylindrical microlens in the direction of the second coordinate axis), and the reflective facets of the second type have an inclination whose component β _{2 is given} in the direction of the second coordinate axis by $$\left|{\beta }_1-{\beta }_2\right|>10°\mathrm{,}$$

It has been found that significant contrast enhancement for tilted lens faceted reflective facets only occurs to about the angle calculated with relationship (1A) above. On the other hand, the use of reflective facets with gradients greater than β ₁ makes it possible to at least not significantly increase the contrast compared to facets with low inclination or facets with a slope equal to zero. Motivational images with reflective facets, which are designed according to the above relationships (FIG. 1A) and / or (1B), thus enable high-contrast representations while at the same time being easy to produce, as will be explained in more detail below.

The orientation of the facets is determined here by the inclination and the azimuth angle of the reflective facets. Of course, the orientation of the facets can also be determined by other parameters. In particular, these are two mutually orthogonal parameters, such. B. the two components of the normal vector of each facet.

The motif image of the representation arrangement is preferably in the focal plane of the microlenses.

In an advantageous embodiment, the inclination β _{2 of} the reflective facets of the second type is given by | β ₁ - β ₂ | > 15 °. In particular, the inclination β _{2 of} the reflective facets of the second type can be zero.

Advantageously, the reflective facets, in particular the reflective facets of the first type, form a periodic or aperiodic sawtooth grid. In the case of aperiodic gratings, diffraction effects, in particular color effects, such as e.g. diffractive Farbeinstreuung be suppressed. Furthermore, with aperiodic gratings, it is also possible to avoid unwanted moiré effects, such as those that can arise when superimposing periodic gratings and lenticular grids. The grating period of the reflective facets is preferably between 2.5 μm and 100 μm, preferably between 3 μm and 15 μm.

In advantageous embodiments, the grating period of the reflective facets of the first and / or second type continues in each case over all unit cells with the same phase. Also advantageously, the grating period and the phase of the grating of the reflective facets of the first and / or the second type may be the same for all unit cells, respectively. The design of all lattices with the same phase and period (both types and in all unit cells) may be particularly advantageous in their manufacture, for example, when the lattices of the reflective facets of the first and the second type have opposite inclinations. Alternatively, can, for. Example, to avoid unwanted moire effects, the grating period and / or the phase of the grating of the reflective facets of the first and / or the second type of unit cell to unit cell different. Especially For example, the grating period and / or the phase of the reflective facets of the first and / or the second type may have a substantially random variation at least in regions.

In a likewise advantageous embodiment, the reflective facets of the first and / or the second type per unit cell have multiple facets with the same inclination.

Advantageously, the inclination and / or the azimuth angle of the reflective facets of the second type have an essentially random variation at least in regions. The differently oriented reflective facets create a kind of glittering effect, which can enhance the contrast to the reflective facets of the first kind.

The chosen formulation, according to which the grating period, the phase, the inclination and / or the azimuth angle of the facets have a substantially random variation in regions, takes account of the fact that a random variation can also be realized for example by means of computer-generated "random numbers", strictly speaking, they are deterministic.

Advantageously, additionally or alternatively, the structure depth and / or optionally the grating period of the reflective facets of the second type can be varied.

The inclination of the reflective facets of the first and / or second type may also change continuously, at least in some areas. This can be used, for example, to create running effects or appearing three-dimensionally arched.

The facets are preferably formed as substantially planar surface pieces, which facilitates the production. The chosen formulation, according to which the facets are formed as essentially flat surface pieces, takes account of the fact that in practice production-related generally never perfectly flat surface pieces can be produced. The facets may alternatively also be formed as curved (eg concave, convex or wavy) patches. The curvature of the patches is expediently low.

In the case of the security element according to the invention, the number of reflective facets can in particular be selected so that a maximum predetermined facet height or structural depth of the facets is not exceeded. In particular, the facets have a structure depth of 0 μm to 10 μm, preferably of 1.5 μm to 4 μm.

The diameter of the spherical or aspherical microlenses or the extent of the cylindrical microlenses in the transverse direction is advantageously between 5 .mu.m and 100 .mu.m, preferably between 10 .mu.m and 30 .mu.m. The expansion of the cylindrical microlenses in the direction of the first coordinate axis is expediently more than 250 μm, preferably more than 500 μm, particularly preferably more than 2 mm.

In the case of the security element according to the invention, a reflective or reflection-increasing coating can be formed on the facets at least in regions. Reflection-enhancing coatings in the context of the invention are also coatings that increase the reflectance, for example, only from about 20% to about 50%, such as semitransparent layers, whereas in reflective coatings a very high Reflectance is present. The reflective or reflection-enhancing coating may be a metallic coating, for example vapor-deposited. In particular aluminum, gold, silver, copper, palladium, chromium, nickel and / or tungsten and their alloys can be used as the coating material. Alternatively, the reflective or reflection-enhancing coating may be formed by a coating with a high refractive index material.

In advantageous embodiments, the reflective or reflection-enhancing coating may be formed only in regions, preferably in the form of patterns, characters or a coding, which form a macroscopic additional motif visible to the naked eye without aids, in particular without magnification by the microlenses.

In particular, a color-shifting layer may be formed on the facets at least in regions. According to an advantageous embodiment, regions of different color-shifting layers can also be formed on the facets. Both the reflection-enhancing coating and the color-shifting layer may be in the form of patterns, characters or codes and / or have recesses in the form of patterns, characters or codes.

The color-shifting layer can be designed in particular as a thin-layer system or thin-film interference coating. In this case, for example, a layer sequence metal layer / dielectric layer / metal layer or a layer sequence of at least three dielectric layers, wherein the refractive index of the middle layer is less than the refractive index of the other two layers can be realized. As the dielectric material, for example, ZnS, SiO ₂ , TiO ₂ , MgF ₂ can be used.

The color-shifting layer can also be formed as interference filter, thin semitransparent metal layer with selective transmission by plasmon resonance effects, nanoparticles, etc. The color-shifting layer can in particular also be realized as a liquid-crystal layer. A thin-film system with a reflector / dielectric / absorber structure is also possible.

In further advantageous embodiments, an additional structuring, preferably a diffractive structure, a structure having a matting or scattering effect, and / or a nanostructuring, in particular by colored sub-wavelength structures reflecting into the zeroth diffraction order, is provided on a part of the reflective facets. In particular, a non-diffractive matt structure may be provided on the reflective facets of the second type.

The arrangement of the microlenses can expediently be provided with a protective layer whose refractive index preferably deviates by at least 0.3 from the refractive index of the microlenses. In this case, the focal length of the lenses changes due to the protective layer, which must be taken into account in the dimensioning of the lens radii of curvature and / or the thickness of the spacer layer. In addition to protection against environmental influences, such a protective layer also prevents the lenses from easily being molded for counterfeiting purposes.

The representation arrangement itself can be an arrangement for the unscaled representation of target images and in particular a change image, a motion image, a pump image, a morph image or a stereo image, but with advantage also a micro-optical representation arrangement, in particular a Moiré magnification device, Moire-type magnification device or modulo magnification device. The basic principle of such micro-optical representation arrangements is in the documents WO 2007/076952 . WO 2009/000529 and WO 2009/000528 whose disclosure content is included in this description in this respect. All of these micro-optical magnification arrangements contain a motif image with micromotif image parts which, when viewed with a suitably coordinated viewing grid, reconstructs a predetermined target image.

In micro-optical display arrangements, such as moiré magnification arrangements, both the raster of the image objects and the lenticular grid are usually produced by UV embossing on opposite sides of a carrier film. The thickness of the carrier film is dimensioned such that, taking into account the two residual coating thicknesses, the image objects are located exactly in the focal plane of the microlenses. However, the moiré-magnified image becomes blurred if the position of the image objects deviates too far from the focal plane.

In the case of unscaled systems, for example in the case of non-enlarging change images, the motif image can also lie in a plane (parallel) which deviates slightly from the focal plane of the microlenses. In this case, only the angular ranges in which transitions take place between different target images increase at the expense of the angular ranges in each of which only one target image is visible. By contrast, the sharpness of the target images, which is significantly more important for the visual appearance, is not affected by the deviation.

This effect can also be used specifically to the thickness of the carrier film or a spacer layer and thus the total thickness of the security element continue to reduce. It should be borne in mind that deviations of the motif image plane from the focal plane here also lead to a fanning out of the radiation beams of the reflected radiation and thus may possibly reduce the contrast.

In an advantageous embodiment, in a security element having a representation arrangement for the unscaled representation of target images, each of the elementary cells is divided into two or more subareas. Each of these sub-areas is assigned to exactly one of the target images and each contains an unscaled section of the target image to which the sub-area is assigned. The subareas of the various unit cells can merge in unscaled systems with cylindrical lenses to form contiguous strips.

The relative position of the microlenses and the partial surface of the unit cells each define a viewing angle range from which the target image to which the partial surface is assigned is shown unscaled when viewed. The illustrated target images are each visible from a certain viewing angle range around a central viewing direction, the size of this visibility region being given in particular by the size of the partial surfaces. For the sake of brevity, in the context of this description, reference is sometimes made to a viewing direction, it being understood that this indication includes the visibility range determined by the finite size of the partial areas around this viewing direction.

The security element is advantageously a security thread, a tear thread, a security tape, a security strip, a patch or a label for application to a security paper, document of value or the like.

The invention also includes a data carrier equipped with a security element of the type described above. The security element may in particular be embedded in the data carrier or applied to the data carrier.

• zur Erzeugung einer Darstellungsanordnung ein Motivbild beabstandet von einem Linsenraster angeordnet wird, so dass das Motivbild bei Betrachtung mit dem Linsenraster die vorbestimmten Sollbilder zeigt, wobei
• das Linsenraster aus einer Mehrzahl von sphärischen oder asphärischen Mikrolinsen gebildet wird und
• das Motivbild aus einer Mehrzahl von Elementarzellen gebildet wird, wobei das Motivbild eine Mehrzahl von reflektiven Facetten mindestens einer ersten und einer zweiten Art umfasst, die sich hinsichtlich ihrer Neigung unterscheiden und die bei Betrachtung mit dem Linsenraster die visuell erkennbaren, kontrastierenden Bildbereiche der Sollbilder erzeugen, wobei
• die reflektiven Facetten der ersten Art eine Neigung β₁ aufweisen, die gegeben ist durch $$0,85\cdot {\beta }^{*}<{\mathrm{<figure-callout\; id="1"\; label="\beta "\; filenames="imgf0001.png"\; state="\{\{state\}\}">\beta </figure-callout>}}_1<1,15\cdot {\beta }^{*}$$
  
  
  mit $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{h}\right)}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}\right)},$$
  
  
  wobei f die Brennweite der Mikrolinse, h die Höhe der Mikrolinse im Scheitel, R den Krümmungsradius im Zentrum der Mikrolinse und r den Linsenradius der Mikrolinse darstellen, und
• die reflektiven Facetten der zweiten Art eine Neigung β₂ aufweisen, die gegeben ist durch |β ₁ - β₂| > 10°.

The invention further includes a method for producing a security element having a representation arrangement for displaying one or more target images whose motifs are each formed by visually recognizable, contrasting image regions, in which

• for generating a representation arrangement, a motif image is arranged at a distance from a lenticular grid, so that the motif image when viewed with the lenticular grid shows the predetermined target images, wherein
• the lenticular grid is formed from a plurality of spherical or aspherical microlenses, and
• the motif image is formed from a plurality of unit cells, wherein the motif image comprises a plurality of reflective facets of at least a first and a second type which differ in their inclination and which, when viewed with the lenticular grid, produce the visually recognizable, contrasting image areas of the target images, in which
• the reflective facets of the first type have an inclination β ₁ , which is given by $$0.85\cdot {\beta }^{*}<{\mathrm{<figure-callout\; id="1"\; label="\beta "\; filenames="imgf0001.png"\; state="\{\{state\}\}">\beta </figure-callout>}}_1<1.15\cdot {\beta }^{*}$$
  
  
  With $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{H}\right)}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}\right)}.$$
  
  
  where f is the focal length of the microlens, h is the height of the microlens at the apex, R is the radius of curvature in the center of the microlens, and r is the lens radius of the microlens, and
• the reflective facets of the second kind have an inclination β ₂ given by | β ₁ - β ₂ | > 10 °.

• zur Erzeugung einer Darstellungsanordnung ein Motivbild beabstandet von einem Linsenraster angeordnet wird, so dass das Motivbild bei Betrachtung mit dem Linsenraster die vorbestimmten Sollbilder zeigt, wobei
• das Linsenraster aus einer Mehrzahl von zylindrischen Mikrolinsen gebildet wird, die in einem Raster angeordnet sind, durch welches ein Koordinatensystem mit einer ersten Koordinatenachse, die durch die Brennpunktlinien der zylindrischen Mikrolinsen bestimmt ist, und einer zweiten Koordinatenachse aufgespannt ist, die senkrecht auf der ersten Koordinatenachse steht,
• das Motivbild aus einer Mehrzahl von Elementarzellen gebildet wird, wobei das Motivbild eine Mehrzahl von reflektiven Facetten mindestens einer ersten und einer zweiten Art umfasst, die sich hinsichtlich ihrer Neigung unterscheiden und die bei Betrachtung mit dem Linsenraster die visuell erkennbaren, kontrastierenden Bildbereiche der Sollbilder erzeugen, wobei
• die reflektiven Facetten der ersten Art eine Neigung aufweisen, deren Komponente β₁ in Richtung der zweiten Koordinatenachse gegeben ist durch $$0,85\cdot {\beta }^{*}<{\mathrm{<figure-callout\; id="1"\; label="\beta "\; filenames="imgf0001.png"\; state="\{\{state\}\}">\beta </figure-callout>}}_1<1,15\cdot {\beta }^{*}$$
  
  
  mit $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{h}\right)}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}\right)},$$
  
  
  wobei f die Brennweite der zylindrischen Mikrolinse, h die Höhe der zylinderischen Mikrolinse im Scheitel, R den Krümmungsradius im Zentrum der zylindrischen Mikrolinse und r den Linsenradius der zylindrischen Mikrolinse darstellen, und
• die reflektiven Facetten der zweiten Art eine Neigung aufweisen, deren Komponente β₂ in Richtung der zweiten Koordinatenachse gegeben ist durch |β ₁-β ₂| >10°.

In addition, the invention also includes a method for producing a security element with a representation arrangement for displaying one or more target images whose motifs are each formed by visually recognizable, contrasting image areas, in which

• for generating a representation arrangement, a motif image is arranged at a distance from a lenticular grid, so that the motif image when viewed with the lenticular grid shows the predetermined target images, wherein
• the lenticular grid is formed of a plurality of cylindrical microlenses arranged in a grid through which a coordinate system is spanned having a first coordinate axis defined by the focal lines of the cylindrical microlenses and a second coordinate axis perpendicular to the first coordinate axis stands,
• the motif image is formed from a plurality of unit cells, wherein the motif image comprises a plurality of reflective facets of at least a first and a second type which differ in their inclination and which, when viewed with the lenticular grid, produce the visually recognizable, contrasting image areas of the target images, in which
• the reflective facets of the first type have an inclination whose component β _{1 is given} in the direction of the second coordinate axis by $$0.85\cdot {\beta }^{*}<{\mathrm{<figure-callout\; id="1"\; label="\beta "\; filenames="imgf0001.png"\; state="\{\{state\}\}">\beta </figure-callout>}}_1<1.15\cdot {\beta }^{*}$$
  
  
  With $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{H}\right)}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}\right)}.$$
  
  
  where f is the focal length of the cylindrical microlens, h is the height of the cylindrical microlens at the apex, R is the radius of curvature in the center of the cylindrical microlens and r represent the lens radius of the cylindrical microlens, and
• the reflective facets of the second type have an inclination whose component β ₂ in the direction of the second coordinate axis is given by | β ₁ - β ₂ | > 10 °.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the specified combinations but also in other combinations or alone, without departing from the scope of the present invention.

Further exemplary embodiments and advantages of the invention are explained below with reference to the figures, in the representation of which a representation true to scale and proportion has been dispensed with in order to increase the clarity.

Fig.1

eine schematische Darstellung einer Banknote mit einem erfindungsgemäßen Sicherheitselement, das eine Moire-Vergrößerungsanordnung enthält,

Fig. 2

schematisch den Aufbau eines erfindungsgemäßen Sicherheitselements, beispielsweise eines Transferelements im Querschnitt,

Fig. 3

schematisch die Wirkungsweise von Mikrospiegeln, wie sie in erfindungsgemäßen Darstellungsanordnungen eingesetzt werden, wobei (a) und (b) jeweils eine Querschnittsansicht einer Moiré-Vergrößerungsanordnung zeigen,

Fig. 4

schematisch die Verhältnisse bei der Betrachtung einer erfindungsgemäßen Darstellungsanordnung zur Definition der auftretenden Größen,

Fig. 5

schematisch einen Ausschnitt eines erfindungsgemäßen Sicherheitselements, beispielsweise des Transferelements der Fig. 1, in Aufsicht,

Fig. 6

eine schematische Querschnittsansicht des Sicherheitselements entlang der Linie VI-VI in Figur 5, und

Fig. 7

schematisch eine Querschnittsansicht des Motivbilds eines weiteren erfindungsgemäßen Sicherheitselements.

Show it:

Fig.1

1 a schematic representation of a banknote with a security element according to the invention, which contains a moiré magnification arrangement,

Fig. 2

1 schematically the structure of a security element according to the invention, for example a transfer element in cross-section,

Fig. 3

schematically the mode of action of micromirrors, as used in representation arrangements according to the invention, wherein (a) and (b) each show a cross-sectional view of a moiré magnification arrangement,

Fig. 4

FIG. 2 is a schematic view of the relationships when viewing a representation arrangement according to the invention for defining the occurring variables. FIG.

Fig. 5

schematically a section of a security element according to the invention, for example, the transfer element of Fig. 1 , in supervision,

Fig. 6

a schematic cross-sectional view of the security element along the line VI-VI in FIG. 5 , and

Fig. 7

schematically a cross-sectional view of the motif image of another security element according to the invention.

The invention will now be explained using the example of security elements for banknotes and other value documents. FIG. 1 shows a schematic representation of a banknote 10, which is provided with a security element according to the invention in the form of a glued transfer element 12. In the exemplary embodiment, the transfer element 12 represents a moire magnification arrangement, which presents a target image 14 to the viewer. The target image 14 shows a motif that is formed by visually recognizable and contrasting image areas 16 and 17, respectively.

In the embodiment, the motif of the target image is formed by shiny metallic, dark appearing letters "PL" in front of a likewise shiny metallic, but bright appearing background (shown here by the black letters "PL" in front of white background). It is understood that in practice mostly complex motifs, for example the denomination of the banknote, geometric patterns, portraits, architectural, technical or nature motives are used. The motifs can also be present in particular in the form of screened half-tone representations.

However, the invention is not limited in any way to Moire magnification arrangements. On the contrary, the invention can be applied to all display arrangements with a contrasting reflective motif layer, in particular also in moire-type magnification arrangements, modulo magnification arrangements, or also in change pictures, motion pictures, pump pictures, morph pictures or stereo pictures of unscaled representing systems.

The invention is also not limited to the banknote transfer elements used for illustration, but may also be used, for example, in security threads, wide security strips or cover sheets placed over a window area or through opening of a document. In particular, it is also conceivable that the microlenses or the reflective facets are applied to or introduced into different sides of an at least partially transparent banknote substrate, for example a substrate made of polymeric material.

FIG. 2 schematically shows the structure of a security element 20 according to the invention, for example a transfer element, in cross section. Shown here are, as in the other figures, only necessary for the explanation of the principle of operation parts of the structure.

The security element 20 of Fig. 2 has a carrier 22 in the form of a transparent plastic film, for example, about 20 microns thick PET film. In the exemplary embodiment, the upper side of the carrier 22 is provided with a viewing grid in the form of a grid-shaped arrangement of spherically or aspherically configured microlenses 24 whose diameter d in the exemplary embodiment is d = 20 μm. The microlenses 24 form on the surface of the carrier film 22 a two-dimensional Bravais grid with a preselected symmetry. The Bravais grating, for example, have a hexagonal lattice symmetry. However, other, in particular lower symmetries and thus more general forms, such as the symmetry of a parallelogram grating, are also possible. There may also be regions of different symmetries or Bravais lattice.

The distance of adjacent microlenses 24 is preferably chosen as small as possible in order to ensure the highest possible area coverage and thus a high-contrast representation. On the underside of the carrier 22, a motif layer 26 is formed, which contains a divided into a plurality of unit cells 28 motif image with microimage regions 29A and 29B. The arrangement of the unit cells 28 also forms a two-dimensional Bravais grating with a preselected symmetry.

In the case of a moiré magnification arrangement, the Bravais grating of the unit cells 28 differs slightly in its orientation and / or in the size of its grating parameters from the Bravais grating of the microlenses 24. Depending on the nature and size of the difference arises when viewing the motif image an enlarged picture of the microimage areas.

The optical thickness of the carrier film 22 and the focal length of the microlenses 24 are matched to one another such that the motif layer 26 is located approximately at a distance from the lens focal length or in the focal plane. The carrier foil 22 thus forms an optical spacer layer which ensures a desired, constant spacing of the microlenses 24 and the motif layer 26 with the motif image.

When the motif image 26 is viewed with the lenticular grid, the motif is reconstructed from the imaged microimage regions 29A, 29B arranged in the unit cells 28, whereby the motif can float in front of and / or behind the image plane or lie in the image plane, depending on the design of the presentation arrangement.

As in Fig. 2 The security element 20 typically includes further layers 32, such as protective, masking or other functional layers, which are not essential to the present invention and therefore will not be described further. A protective layer (not shown here) may also be provided on the microlenses, the refractive index of which preferably deviates by at least 0.3 from the refractive index of the microlenses.

Moiré magnification arrangements showing different colored motifs are known. In order to produce the differently colored motifs, the motif parts lying in the individual microimage regions 29A, 29B are printed, for example, in the desired shape. The peculiarity of the depiction arrangements described here consists in the fact that the motif of the target image 14 is formed by contrasting, differently reflecting image areas 16, 17. In order to create a motif with different reflection properties, those in the individual microimage areas 29A, 29B lying subject parts of the target image 14 according to the invention formed by differently oriented reliefs. In order to ensure a sufficient contrast, the procedure is as follows.

The structure and the basic mode of operation of a security element 20 according to the invention, for example of the transfer element 12 of FIG Fig. 1 , is now referring to the FIGS. 3 to 7 described in more detail.

In FIG. 3 the basic structure of a representation arrangement 40 according to the invention is shown. There, assuming idealized (spherical or cylindrical) lenses, the beam path of the right or left marginal rays for the case of vertical incidence of light (corresponding to vertical plan view) is shown by way of example. It is further assumed that the micromirrors are located in the focal plane of the lenses.

In the in FIG. 3 shown sections of the display assembly 40 are each arranged under a microlens, formed as micromirrors facets 42-1 and 42-2 of a first and a second type shown in a section through the yz plane. The micromirrors 42 - 1, 42 - 2 each have a reflection surface 44 - 1, 44 - 2, which is the optically effective surface of the facet and whose orientation is determined by the indication of the inclination.

Fig. 3 (a) shows the case that the reflection surface 44-2 of the micromirror 42-2 is not inclined against the surface of the lens assembly. For the micromirror shown β is therefore equal to zero. The incident radiation (light rays L1, L2) in this case is reflected in the same direction from which it entered. The light beams L1, L2 leave the lens assembly through the lens through which they have also fallen and are all reflected back in the same direction.

At the in Fig. 3 (b) In the case shown, the reflection surface of the micromirror 42-1 is against the surface of the lens arrangement (and in the case of cylindrical lenses perpendicular to the longitudinal direction of the cylindrical lenses or in the direction of curvature of the cylindrical lenses) with the inclination | β |> 0 ° inclined.

As in Fig. 3 (b) 4, the portion of the radiation which, after reflection at the micromirror 42-1 leaves the lens arrangement through the lens through which it has sunk, also leaves the lens arrangement vertically upwards. The inclination β of the micromirror 42-1 has no influence on the direction of propagation in this part of the radiation (see light beam L1: after leaving the lens, the propagation direction essentially corresponds to the propagation direction of the radiation in the direction of propagation FIG. 3 (a) illustrated case, wherein the light beam L1 exits only slightly offset in comparison). However, some of the radiation (here the light beam L2) passes the lens after reflection at the micromirror 42-1 and exits the arrangement for example through an adjacent lens. In this case, the propagation direction of the light beams is changed. Upon leaving, the light beam L2 propagates in a direction determined by refraction at the surface of the first lens, tilt of the micromirror with respect to the surface of the lens assembly, and refraction at the surface of an adjacent (and not shown) second lens.

This creates a contrast to the in Fig. 3 (a) shown case in which the reflection surface of the micromirror is not inclined against the surface of the lens assembly (β = 0 °). Although a part of the radiation (for example light beam L1) behaves practically like in FIG Fig. 3 (a) shown the simplest case. The remaining part of the radiation, however, the propagation direction is changed. Looking from direction Therefore, the representation arrangement appears darker in the area of the facet 42-1 than in the area of the facet 42-2. According to the invention, it is now provided to increase this part of the radiation and thus the contrast.

Whether the area of facet 42-1 or the area of facet 42-2 appears lighter or darker depends ultimately on how the environment is illuminated. An observer looks into a solid angle of the environment that is more or less fanned out by refraction of the light rays on the surface of the lenses, reflection on the facets and refraction on the surface of the lenses. The brightness of the environment in this solid angle range dictates whether the associated area appears bright or dark to the viewer. The larger the solid angle range, the larger the range over which the brightness of the environment is practically averaged and the weaker the contrast.

In the schematic representation in FIG. 4 By way of example, the beam path of the rays which are incident perpendicularly in the center or in the edge region of the lens is shown (light rays L3, L4, L5). It is further assumed that the micromirror or the facet 42-1 is located in the focal plane of the (idealized spherical) lens 24.

As in FIG. 4 1, a micromirror must be inclined at approximately the angle β * to the horizontal, so that the light rays L3, L4, L5 incident through the overlying microlens 24 (perpendicularly) no longer return there, but are deflected into an area adjacent to this lens.

wobei f die Brennweite der Mikrolinse, h die Höhe der Mikrolinse im Scheitel, R den Krümmungsradius im Zentrum der Mikrolinse und r den Linsenradius der Mikrolinse darstellen. Für die Neigung β₁ der reflektiven Facetten 42-1 der ersten Art kann daher angenommen werden: $$0,85\cdot {\beta }^{*}<{\beta }_1<1,15\cdot {\beta }^{*},$$

d. h. die reflektiven Facetten der ersten Art können erfindungsgemäß auch eine Neigung β₁ aufweisen, die um weniger als ± 15 % von β* abweicht.It therefore approximates: $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{H}\right)}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}\right)}.$$

where f is the focal length of the microlens, h is the height of the microlens at the apex, R is the radius of curvature in the center of the microlens, and r is the lens radius of the microlens. For the inclination β _{1 of} the reflective facets 42-1 of the first type, it can therefore be assumed: $$0.85\cdot {\beta }^{*}<{\mathrm{<figure-callout\; id="1"\; label="\beta "\; filenames="imgf0001.png"\; state="\{\{state\}\}">\beta </figure-callout>}}_1<1.15\cdot {\beta }^{*}.$$

ie the reflective facets of the first type can according to the invention also have an inclination β ₁ which deviates by less than ± 15% from β *.

The above condition also applies to cylindrical microlenses in which the reflective facets have an inclination β ₁ in a direction perpendicular to the focal lines or parallel to the second coordinate axis, where R is the radius of curvature in the center of the cylindrical microlens and r is the radius of the cylindrical lens Represent microlens.

For a refractive index of the lens material n _ML = 1.5, as can be assumed for conventional plastics and UV lacquer layers, and a refractive index of the material surrounding the microlens (air) nL = 1.0, the condition is obtained $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{3\mathrm{R}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}}=\pm \arctan \frac{\mathrm{r}}{2\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}}\mathrm{,}$$

With a lens diameter d = 22 μm (or r = 11 μm) and a radius of curvature R = 12 μm in the center of the microlens, this results an inclination β * = 21 °. The inclination β _{1 of} the reflective facets of the first kind can accordingly lie between 17.85 ° and 21.15 °.

Without being bound by this explanation, for inclinations up to this value there is a continuous increase in the proportion of the radiation reflected next to the lens and, correspondingly, an increase in contrast with no or only slightly inclined reflective facets when viewed with a lenticular grid. From approximately an inclination β *, the light rays L3, L4, L5 incident through the microlens above are for the most part deflected or reflected, at least when viewed vertically, into a region adjacent to this lens.

It has also been found that the use of reflective facets with inclinations greater than β ₁ can at least no longer substantially increase the contrast with respect to facets of a second type with a lower inclination β ₂ or with an inclination β ₂ equal to zero. Also, the use of such reflective facets - with significantly larger inclinations - be associated with difficulties in manufacturing. For optimum contrast, the reflective facets of the second type have according to the invention an inclination β ₂ , which is given by | β ₁ - β ₂ | > 10 °, ie at least 10 ° smaller than the inclination β ₁ .

Motivational images with reflective facets of a first and second type, which are designed according to the above conditions, thus allow sufficient contrast at a producible by a minimum embossing height ease of manufacture. In particular, this makes it difficult to achieve, for example, the fact that facets have large aspect ratios, in particular aspect ratios> 1, ie one compared to the feature size have large structural depth, avoid or at least reduce during production.

The motif image 26 is composed according to the invention of a plurality of identical unit cells 28, of which some in some FIG. 5 are shown in a schematic manner, wherein, as in the other figures, only the parts of the structure required for the explanation of the principle of operation are shown.

For the exemplary moiré magnification arrangement of the security element 30, the unit cells 28 of the motif image 26, as explained above, are arranged next to one another in a grid, matching the grid of the microlenses 24. In the FIG. 5 shown unit cells 28 are arranged here for the sake of simplicity as well as the microlenses 24 in a hexagonal grid.

The motif image 26 contains two types of reflective facets 33-1 and 33-2, which differ in their orientation and, when viewed with the lenticular grid, produce the visually recognizable, contrasting image areas of the target image 14. In this case, the facets 33-1 form a first microimage region 29A, for example a foreground, the facets 33-2 form a second microimage region 29B, for example a background.

The invention is not limited to the subdivision into two types of facets. Rather, other types of facets may be provided with different orientation, for example, to produce different light-dark effects or to generate a grayscale image.

In FIG. 6 is the sectional view taken along the line VI-VI of FIG. 5 represented, wherein the representation in FIG. 6 as well as in the other figures is not true to scale, but partly greatly exaggerated for better presentation. Furthermore, to simplify the illustration in FIG FIG. 6 as well as in FIG. 7 an optional existing reflective or high refractive coating on the facets 33-1, 33-2 not shown.

Regarding FIG. 6 For example, the motif layer comprises a embossing layer 36 applied to the carrier 22, in which the reflective facets 33-1, 33-2 are formed. The embossed layer 36 structured in this way is preferably coated with a reflective or reflection-enhancing coating. On the embossing layer 36, a metal, for example aluminum, can be vapor-deposited over the full area, so that a full-surface metal coating is formed.

As in FIG. 6 is shown, the inclination β ₁ is the same for all facets 33-1 and in the exemplary embodiment is 21 °. The grating period of the facets 33-1 forming a periodic sawtooth grid is preferably between 2.5 μm and 100 μm and in particular between 3 μm and 20 μm. For example, the grating period is 4 μm. The inclination β _{2 of} the facets 33-2 of the second type is 0 °. In the exemplary embodiment, the facets 33-1 form a foreground, here the letter "A", the facets 33-2 a background.

Depending on the viewing or lighting situation, the facets 33-1 or the facets 33-2 appear bright when viewed through the lenticular. When tilting the security element in a direction parallel to the inclination β _{1 of} the facet 33-1 (or in the case of cylindrical microlenses in a direction parallel to the second coordinate axis), the viewer can therefore perceive a contrast change in the subject, ie previously bright-appearing image areas of the subject then appear dark, previously dark appearing image areas of the subject appear bright after tilting.

At the in FIG. 6 The grating period and the phase of the grating are identical for each unit cell 28, respectively, as shown in FIGS. In an alternative not shown here, however, the grating period of the facets 33 - 1 can also continue over all elementary cells 28 with the same phase, whereby, for example, unwanted effects caused by moire magnification of the boundaries of the facets 33 - 1 can be prevented.

FIG. 7 shows another way to increase the light-dark contrast. As illustrated there by way of example on the basis of the cross-sectional view of some unit cells of the motif image and as can be seen in particular from the detail view, the second image area of the target image 14 can also be formed by a plurality of reflective facets 33-2. The reflective facets 33-2 can have different orientations, whereby a kind of glittering effect can be realized. In the exemplary embodiment, the facets 33-2 differ in their inclinations β ₂ . In order to ensure a sufficient contrast to the facets 33-1 of the first type, the inclinations β _{2 of} the facets 33-2 must also be at least 10 ° smaller than those of the facets 33-1 and may for example be between 0 ° and 5 ° For example, while the inclination β ₁ of the first type facets 33-1 is the same for all facets 33-1 and is 23 °, for example.

In an alternative embodiment, not shown here, the azimuth angle of the facets 33-2 of the second type may additionally or alternatively also vary. Preferably, the inclination β ₂ and / or the azimuth angle of Reflective facets 33-2 of the second type at least partially on a substantially random variation and therefore reflect light in different directions slightly different from the light incident direction. The glittering effect thus produced further increases the contrast with the reflective facets 33-1.

In further embodiments, the reflective or reflection-enhancing coating can also be present only in regions, in particular in the form of patterns, characters or a coding. Thus, the facets provided with a metal coating can be partially metallized or demetallized in the form of a symbol or a value number.

Such effects are unusual and surprising for a viewer and therefore lead to a visually attractive and eye-catching overall impression with high attention and recognition value.

A possible manufacturing method for such only partially coated facets is in the WO 2011/138039 A1 described. In order to avoid coating defects which may arise, for example, in the case of large contiguous depression areas due to the undesired removal or transfer of the coating, supporting structures in the form of small raised elements, in particular webs or supporting pillars, are optionally provided between the subregions.

The regional removal of the reflective or reflection-enhancing coating in the individual partial surfaces can, for example, also be effected by laser ablation of the coating through the lenses.

In further embodiments, not shown here, a part of the facets may additionally be provided with a further, finer structuring. Such structuring is formed, for example, by nanostructuring, in particular by colored subwavelength structures which reflect into the zeroth diffraction order. Of course, other structures, such as nanostructures such as moth-eye structures, or diffractive microrelief structures carrying holographic information are also possible. In particular, the reflectivity of the facets 33-2 of the second type can be advantageously influenced by non-diffractive matt structures, while the use of a nanostructuring such as, for B. moth-eye structures in the facets 33-1 of the first type has proved advantageous.

LIST OF REFERENCE NUMBERS

10

bill

12

transfer element

14

target image

16

Image area of the target image

17

Image area of the target image

19

tilt direction

20

security element

22

carrier

24

microlenses

26

motif layer

28

unit cell

29A, 29B

Micro image area

30

security element

32

more layers

33-1,33-2

facet

36

embossing layer

40

representation arrangement

42-1,42-2

facet

44-1,44-2

reflecting surface

50

security element

d

Lens diameter

f

focal length

L1, L2, L3, L4, L5

radiation

r

lens radius

R

radius of curvature

β, β *, β ₁ , β ₂

Tilt

Claims (20)

Security element for securing security papers, value documents and other data carriers, comprising a representation arrangement for displaying one or more target images, whose motifs are each formed by visually recognizable, contrasting image regions, wherein the display arrangement comprises a lenticular grid and a motif image arranged at a distance from the lenticular grid, which when viewed with the lenticular grid shows the predetermined target images, wherein - The lenticular grid is formed from a plurality of spherical or aspherical microlenses and the motif image is formed from a plurality of unit cells,
characterized in that the motif image comprises a plurality of reflective facets of at least a first and a second type which differ in their inclination and which, when viewed with the lens grid, produce the visually recognizable, contrasting image areas of the target images, - The reflective facets of the first type have an inclination β ₁ , which is given by $$0.85\cdot {\beta }^{*}<{\beta }_1<1.15\cdot {\beta }^{*}$$

With $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}\right)}.$$

where f is the focal length of the microlens, R is the radius of curvature in the center of the microlens and r is the lens radius of the microlens, and - The reflective facets of the second type have an inclination β ₂ , which is given by | β ₁ - β ₂ | > 10 °. Security element for securing security papers, value documents and other data carriers, comprising a representation arrangement for displaying one or more target images, whose motifs are each formed by visually recognizable, contrasting image regions, wherein the display arrangement comprises a lenticular grid and a motif image arranged at a distance from the lenticular grid, which when viewed with the lenticular grid shows the predetermined target images, wherein - The lenticular grid is formed of a plurality of cylindrical microlenses, which are arranged in a grid, through which a coordinate system with a first coordinate axis, which is determined by the focal lines of the cylindrical microlenses, and a second coordinate axis is perpendicular to the first Coordinate axis stands, the motif image is formed from a plurality of unit cells,
characterized in that the motif image comprises a plurality of reflective facets of at least a first and a second type which differ in their inclination and which, when viewed with the lens grid, produce the visually recognizable, contrasting image areas of the target images, - The reflective facets of the first type have an inclination whose component β ₁ in the direction of the second coordinate axis is given by $$0.85\cdot {\beta }^{*}<{\beta }_1<1.15\cdot {\beta }^{*}$$

With $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}\right)}$$

where f is the focal length of the cylindrical microlens, R is the radius of curvature in the center of the cylindrical microlens, and r is the lens radius of the cylindrical microlens, and - The reflective facets of the second type have an inclination whose component β _{2 is given} in the direction of the second coordinate axis by | β ₁ - β ₂ | > 10 °. Security element according to claim 1 or 2, characterized in that the inclination β _{2 of} the reflective facets of the second type is given by | β ₁ - β ₂ | > 15 °, wherein the inclination β _{2 of} the reflective facets of the second type is preferably zero. Security element according to one of the above claims, characterized in that the reflective facets, in particular of the first type, form a periodic or aperiodic sawtooth grid. A security element according to claim 4, characterized in that the grating period of the reflective facets is between 2.5 μm and 100 μm, preferably between 3 μm and 15 μm. A security element according to claim 4 or 5, characterized in that the grating period of the reflective facets of the first and / or second type each continues across all unit cells with the same phase or that the grating period and the phase of the grating of the reflective facets of the first and / or second type are the same for all unit cells, respectively, or that the grating period and / or the phase of the reflective facets of the first and / or second type differ from unit cell to unit cell. Security element according to claim 6, characterized in that the grating period and / or the phase of the reflective facets of the first and / or the second type at least partially have a substantially random variation. Security element according to one of the preceding claims, characterized in that the reflective facets of the first and / or the second type per unit cell have multiple facets with the same inclination. Security element according to one of the preceding claims, characterized in that the inclination, the azimuth angle, the structure depth and / or optionally the grating period of the reflective facets of the second type at least partially have a substantially random variation. Security element according to one of the above claims, characterized in that the reflective facets are formed as substantially planar surface pieces. Security element according to one of the above claims, characterized in that the reflective facets have a structure depth of 0 μm to 10 μm, preferably of 1.5 μm to 4 μm. Security element according to one of the above claims, characterized in that the diameter of the spherical or aspherical microlenses or the extent of the cylindrical microlenses in the transverse direction is between 5 μm and 100 μm, preferably between 10 μm and 30 μm. Security element according to one of claims 2 to 12, characterized in that the extension of the cylindrical microlenses in the direction of the first coordinate axis more than 250 microns, preferably more than 500 microns, more preferably more than 2 mm. Security element according to one of the above claims, characterized in that on the reflective facets at least partially a reflective or reflection-enhancing coating is formed, in particular, that the reflective or reflection-enhancing coating regions, preferably in the form of patterns, characters or a coding is formed. Security element according to one of the above claims, characterized in that at least partially a color-shifting coating is formed on the reflective facets. Security element according to one of the above claims, characterized in that an additional structuring, preferably a diffractive structure, a structure having a matting or scattering effect and / or a nanostructuring is provided on a part of the reflective facets. Security element according to one of the preceding claims, characterized in that the security element is a security thread, a tear thread, a security tape, a security strip, a patch or a label for application to a security paper, document of value or the like. Data carrier with a security element according to one of claims 1 to 17. Method for producing a security element having a representation arrangement for displaying one or more target images whose motifs are each formed by visually recognizable, contrasting image regions, in which - To generate a representation arrangement, a motif image spaced from a lenticular grid is arranged, so that the motif image when viewed with the lenticular grid shows the predetermined target images, wherein - The lenticular grid is formed from a plurality of spherical or aspheric microlenses and the motif image is formed from a plurality of unit cells, wherein the motif image comprises a plurality of reflective facets of at least a first and a second type which differ in their inclination and which, when viewed with the lenticular grid, produce the visually recognizable, contrasting image areas of the target images , in which - The reflective facets of the first type have an inclination β ₁ , which is given by $$0.85\cdot {\beta }^{*}<{\beta }_1<1.15\cdot {\beta }^{*}$$

With $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}\right)}.$$

where f is the focal length of the microlens, R is the radius of curvature in the center of the microlens and r is the lens radius of the microlens, and - The reflective facets of the second type have an inclination β ₂ , which is given by | β ₁ - β ₂ | > 10 °. Method for producing a security element with a representation arrangement for displaying one or more target images whose motifs are each formed by visually recognizable, contrasting image areas, in which - To generate a representation arrangement, a motif image spaced from a lenticular grid is arranged, so that the motif image when viewed with the lenticular grid shows the predetermined target images, wherein - The lenticular grid is formed of a plurality of cylindrical microlenses, which are arranged in a grid through which a coordinate system with a first coordinate axis, which is determined by the focal lines of the cylindrical microlenses, and a second coordinate axis is perpendicular to the first Coordinate axis stands, the motif image is formed from a plurality of unit cells, wherein the motif image comprises a plurality of reflective facets of at least a first and a second type which differ in their inclination and which, when viewed with the lenticular grid, produce the visually recognizable, contrasting image areas of the target images , in which - The reflective facets of the first type have an inclination whose component β ₁ in the direction of the second coordinate axis is given by $$0.85\cdot {\beta }^{*}<{\beta }_1<1.15\cdot {\beta }^{*}$$

With $${\beta }^{*}=\pm \arctan \frac{\mathrm{r}}{\left(\mathrm{f}-\mathrm{R}+\sqrt{{\mathrm{R}}^{\mathrm{2}}-{\mathrm{r}}^{\mathrm{2}}}\right)}.$$

where f is the focal length of the cylindrical microlens, R is the radius of curvature in the center of the cylindrical microlens, and r is the lens radius of the cylindrical microlens, and - The reflective facets of the second type have an inclination whose component β _{2 is given} in the direction of the second coordinate axis by | β ₁ - β ₂ | > 10 °.

Images